EP0587125B1

EP0587125B1 - Method and apparatus for winding toroidal coils

Info

Publication number: EP0587125B1
Application number: EP19930114353
Authority: EP
Inventors: Toshio Konno; Kazuhiro Sugai; Shinya Watanabe; Hiroyuki Konno; Tooru Shoji
Original assignee: Tokin Corp
Current assignee: Tokin Corp
Priority date: 1992-09-08
Filing date: 1993-09-07
Publication date: 1997-06-11
Anticipated expiration: 2013-09-07
Also published as: EP0587125A1; DE69311473T2; DE69311473D1

Description

Background of the Invention

This invention relates to a method and a machine for winding a toroidal coil.
In particular, a method and a machine or apparatus for automatically winding a length of wire on a ring-shaped core, with the wire passing through a central aperture of the core are disclosed. As used herein, the term "ring-shaped core" means an article having a closed curve cross-section of a toroid such as a toroidal core or any one of hollow cross-sections.
Methods for winding toroidal coils with a conventional automatic winding machine come into three general categories described below.
In the first method, three rollers are abutted to the peripheral surface of a core to support it rotatably and the wire of a predetermined length is contained within a shuttle in a winding machine. The shuttle carrying a length of wire travels through the central aperture of the core and the wire is drawn out of the shuttle through an opening provided in it. This method is, however, time consuming and ineffective due to the necessity of preparing the wire within the shuttle. In addition, the wire may be rubbed against the periphery of the opening. This may result in some damages on an insulating layer of the wire. Another disadvantage is that the shuttle passes through the central aperture of the core, which restricts the application of it only to relatively large cores. Furthermore, smooth rotation of the core becomes more difficult as the winding proceeds and thus this method sometimes has a trouble in lap winding of the wire.
The second method is directed to a hook-winding of the wire, in which two steps are repeated: to pass the wire of a predetermined length over a surface of the core at one side thereof and to catch the wire with a hook extending from the other side of the core through the central aperture thereof. This method is seriously disadvantageous in that the wire is rubbed against the hook, causing an insulating layer to be damaged.
On the other hand, the third method provides a shuttleless winding machine that requires no hook as well. Instead, the third method requires multiple turning of the core. One end (leading end) of the wire is passed through the central aperture of the core and is extended in the core axial direction. The core is then turned through 180° on a diametrical axis thereof together with the other end (tailing end) of the wire. This turn allows the wire to be laid on the outer periphery of the core. Subsequently, the leading end is again passed through the central aperture to lay the wire on the inner periphery of the core and thus one loop is wound about the core. These steps are repeated until enough wire is wound into a coil. In this event, the core is rotated about its axis by a winding pitch before each turn or reverse through 180°. This rotation is achieved using a pair of core turning clamps. The core turning clamps hold less than the respective halves of the core at the opposing sides thereof and are capable of turning the core in one direction on the diametrical axis thereof. The rotation axes of the core turning clamps cross each other at an angle of the winding pitch. Accordingly, movement of the core turning clamps results in rotation of the core by the winding pitch.
In this method, lap winding can be made by changing the cross angle of the core turning clamps from plus to minus or vice versa. Such rotation relying on changing in holding position may be troubled especially when each clamp holds the core being covered with the first layer of the wire upon lap winding, so that this method also has a disadvantage of potential problems in the subsequent winding.

Summary of the Invention

Accordingly, an object of the present invention is to provide a method and an apparatus for winding toroidal coils with which it is possible to realize lap winding in a high reliability by means of improving the process for turning a core, passing a length of wire through a central aperture of the core and applying tension to the wire.
Another object of the present invention is to provide an automatic winding machine capable of rotating a toroidal core in the circumferential direction to shift the position where the wire is to be wound, thereby avoiding irregular winding of the wire.
These objects are met by a method according to claim 1 and a machine according to claim 5.
Further development of the invention can be obtained from the subclaims.

Brief Description of the Drawing

Fig. 1 shows a schematical appearance of a toroidal coil where a length of wire is wound in double-layer according to a method of the present invention;
Fig. 2 is a plan view showing an essential part of a machine for use in realizing the method of the present invention;
Fig. 3 is a perspective view showing the structure of a tip claw portion of a core turning clamp illustrated in Fig. 2;
Fig. 4 is a perspective view showing the structure of a tip claw portion of a core rotating clamp illustrated in Fig. 2;
Fig. 5 is a perspective view showing the structure of an essential part of a wire chuck assembly illustrated in Fig. 2;
Fig. 6 is a front view of an automatic four-linkage toroidal coil winding machine in which four automatic winding machine shown in Fig. 2 are aligned;
Fig. 7 is a right-hand side view of the automatic four-linkage toroidal coil winding machine shown in Fig. 6;
Fig. 8 is a plan view of an essential part showing position relationship between one of four automatic winding machine 110 and a core/wire feeding machine 116 stopped at a predetermined position in the automatic winding machine 110;
Fig. 9 is a view for use in describing winding process performed by the automatic toroidal coil winding machine ;
Fig. 10 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 11 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 12 is a view showing the structure of another automatic toroidal coil winding machine, in which (A) and (B) are plan and side views, respectively, thereof;
Fig. 13 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 14 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 15 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 16 is a view for use in describing winding process performed by the automatic toroidal coil winding machine;
Fig. 17 is a flow chart for use in describing the winding process performed by the automatic toroidal coil winding machine, laying emphasis on a method for controlling tension applied to the wire; and
Fig. 18 is a side view of a wire chuck assembly for use in describing the automatic toroidal coil winding machine, laying emphasis on a method for controlling tension applied to the wire.

Description of the Preferred Embodiment

An embodiment of the present invention will be described with reference to the drawing. Throughout the following detailed description, similar reference numerals refer to similar elements in all figures of the drawing.
Fig. 1 shows a schematical appearance of a toroidal coil where a length of wire is wound in double-layer according to a method of the present invention. In Fig. 1, the first and second layers of the wire wound on a core 12 is depicted by a broken line 14 and a solid line 16, respectively. One end (leading end) 20 of the wire is passed through a central aperture 22 of the core 12. The other end (tailing end) 24 is radially outwardly extended beyond the core and is turned along with the core 12.
An essential part of an automatic winding machine used for implementing the present invention is shown in a plan view in Fig. 2. In Fig. 2, a core turning clamp 26 and a core rotating clamp 28 are aligned horizontally (parallel to the surface of the figure) in an opposed relation. A wire chuck assembly 30 is disposed beside the core turning clamp 26 and the core rotating clamp 28. A guide rail 32 is elongated vertically (perpendicular to the surface of the figure) to guide the wire chuck assembly 30. In other words, the wire chuck assembly 30 moves upward and downward along the guide rail 32. The core turning clamp 26 and the core rotating clamp 28 are positioned on a horizontal level at approximately half the height of the guide rail 32. The core turning clamp 26 comprises a claw portion 27, an air cylinder 29 and a rotating device 31. The claw portion 27 is located at the tip of the core turning clamp 26. The air cylinder 29 works to advance the tip claw portion 27 (towards the right side of the figure) to close the same. It also works to retract the tip claw portion 27 (toward the left side of the figure) to open the same. The rotating device 31 rotates the tip claw portion 27 about a horizontal axis in one direction.
On the other hand, the core rotating clamp 28 comprises a tip claw portion 33, an air cylinder 35, a mounting plate 37 and a circular rail 39. The claw portion 33 is located at the tip of the core rotating clamp 28. The air cylinder 35 works to advance the tip claw portion 33 (towards the left side of the figure) to close the same. It also works to retract the tip claw portion 33 (toward the right side of the figure) to open the same. The air cylinder 35 is fixed to the mounting plate 37 which moves along the circular rail 39. The circular rail 39 forms a part of the circumference of a circle centered on the central axis (not shown; perpendicular to the surface of Fig. 2) of the core 12 held by the tip claw portion 33. The mounting plate 37 is supported by four rollers 41 along the circular rail 39 so as to be moved rightward and leftward. An air cylinder 43 contributes to move the mounting plate 37 towards the right and left, which results in rotation of the clamped core 12 on the central axis thereof.
The wire chuck assembly 30 comprises a wire chuck holder 49 attached to a shaft of a reciprocating reverse mechanism 47. The reciprocating reverse mechanism 47 is fixed to a base 45. The base 45 slides upward and downward on the elongated vertical guide rail 32.
The claw portion at the tip of the core turning clamp 26 comprises, as shown in Fig. 3, a pair of grasp claws 34 and 36 that moves from left to right in Fig. 2. Urethane rubbers 38 and 42 are attached to the grasp claws 34 and 36, respectively, to hold or grasp a part of the core 12. More particularly, a concave portion 40 is formed in the urethane rubber 38 and the core 12 is pinched between the concave portion and a flat surface of the urethane rubber 42. The rotating device 31 rotates the core turning clamp 26 over 180° in one direction (clockwise), as depicted by an arrow 44, on a rotation axis 46 parallel to the diameter of the core 12. As a result, the core 12 is reversed. The grasp claws 34 and 36 are separated from each other and opened to release the core 12 when the core turning clamp 26 is withdrawn to the left. The concave portion 40 is equal in width to the core 12 and has semi-circular upper and lower surfaces. The semi-circular surfaces are slightly smaller than the half of the core 12. The core turning clamp 26 grasps a part of the core 12 inserted into the concave portion 40. In this event, the tailing end 24 of the wire 18 is held between the flat surfaces of the urethane rubbers 38 and 42. More particularly, the tailing end 24 remains straight to be held in the radial direction of the core 12 depicted by an arrow 48 in Fig. 2. The core 12 is thus turned with the tailing end 24 being held between the urethane rubbers 38 and 42. Longitudinal slots 50 and 52 are formed in the grasp claw 34 and 36, respectively, to facilitate insertion of the leading end 20 of the wire into the center of the claw tip portions. Each of the longitudinal slots 50 and 52 is formed into a half-conical shape. The urethane rubbers 38 and 42 is provided with semi-circular notches 54 and 56, respectively. The notch 54 is communicated with the slot 50 while the notch 56 is communicated with the slot 52. In addition, the semi-circular notches 54 and 56 communicate with the central aperture 22 of the core 12 when a part of it is laid on and held by the concave portion 40.
The tip claw portion of the core rotating clamp 28 comprises, as shown in Fig. 4, grasp claws 58 and 60 and urethane rubbers 62 and 64 as in the core turning clamp 26 shown in Fig. 3. The tip claw portion of the core rotating 28 holds a part of the core 12 upon traveling from right to lift in Fig. 2. The grasp claws 58 and 60 are separated from each other and opened to release the core 12 when the core rotating clamp 28 is withdrawn to the right. Longitudinal slots 66 and 68 are formed in the center of the grasp claw 58 and 60, respectively. Each of the longitudinal slots 66 and 68 is formed into a half-conical shape similar to the slots 50 and 52. The urethane rubbers 62 and 64 is provided with semi-circular notches 70 and 72 (concealed by the core 12), respectively. The notch 70 is communicated with the slot 66 while the notch 72 is communicated with the slot 68. The tip surfaces of the grasp claws 58 and 60 is cutoff obliquely at both sides of the respective slots 66 and 68. The tip surfaces may be cutoff obliquely at either one side of the respective slots 66 and 68. In addition, the urethane rubber 62 of the grasp claw 58 of the core rotating clamp 28 has no concave portion and thus the core 12 is held between the flat surfaces of the urethane rubbers 62 and 64.
Fig. 5 is a perspective view showing the structure of a wire chuck holder 49 of the wire chuck assembly 30. The wire chuck holder 49 is composed of a pull chuck 88 and an insertion chuck 90. The pull chuck 88 is so provided as to be movable upward and downward along two slide shafts 84 and 86 arranged between upper and lower base plates 80 and 82. The slide shafts 84 and 86 are parallel to each other and perpendicular to the base plates 80 and 82. The pull chuck 88 is fixedly secured to the slide shaft 86 and engages the slide shaft 84 with a play. Likewise, the insertion chuck 90 is fixedly secured to the slide shaft 84 and engages the slide shaft 86 with a play. A grasp claw 96 of the pull chuck 88 is driven by an air cylinder 92 while a grasp claw 98 of the insertion chuck 90 is driven by an air cylinder 94. The wire is held by the grasp claws 96 and 98 upon being advanced and is separated therefrom when the grasp claws 96 and 98 are retracted. In this event, operation of the grasp claws 96 can be made independent of that of the grasp claw 98. A screw rod 81 is integrally projected from the insertion chuck 90 at the side of the lower base plate 82 to engage the chuck 90 with the base plate 82 with a play. A nut 83 is threaded outside the lower base plate 82 (see Fig. 13(A)) to keep the insertion chuck 90 away from the pull chuck 88 at a predetermined position closer to the upper base plate 80 through the force of an extension spring 102.
The pull chuck 88 is connected to the upper base plate 80 through an extension spring 100. L-shaped metal fittings 85 (only one is shown in Fig. 5) are secured to both ends of the pull chuck 88. Each of the L-shaped metal fittings 85 is so arranged that one end thereof is projected outward at the side of the insertion chuck 90. An L-shaped plate 85' is secured to one side (closer side to the slide shaft 86 in the figure) of the insertion chuck 90 in an opposed relation with the L-shaped metal fitting 85. An adjusting screw rod 89 is threadedly mounted to the L-shaped plate 85', allowing adjustment of the distance between the L-shaped metal fittings 85 and the end of the screw rod 89. The insertion chuck 90 is connected to the upper base plate 80 through the extension spring 102 and is forced to the pull chuck 88. The chucks 88 and 90 are normally arranged, as will be described later, at a predetermined narrow space. The reciprocating core reverse mechanism 47 in Fig. 2 allows the wire chuck assembly 30 to be reciprocated over 180° in the direction depicted by an arrow 106 on an axis 104 represented by a dot-dash line in Fig. 5. A tip grasp claw 98 of the insertion chuck 90 is provided with a guide 108 for the wire 18.
A short shutter member 91, a long shutter member 93, a first detector 95 and a second detector 97 are for applying a predetermined tension to the wire 18. This will later be described more in detail.
Fig. 6 is a front view of an automatic four-linkage toroidal coil winding machine in which four automatic winding machine shown in Fig. 2 are aligned and Fig. 7 is a right-hand side view thereof.
In these figures, each of four automatic winding machines 110 comprises a core clamp assembly 114 disposed on a rack 112 and the wire chuck assembly 30 capable of sliding along the longitudinal guide rail 32. The wire chuck assembly 30 is integrally connected to a synchronous belt 55 which in turn is connected to a servo-motor 53. The servo-motor 53 is disposed at the top of the guide rail 32. The servo-motor 53 is controlled by voltage and the number of pulses to be supplied thereto a pulse motor 53, thereby the wire chuck assembly 30 rises or is lowered along the guide rail 32.
The core clamp assembly 114 consists of the core turning clamp 26 and the core rotating clamp 28 shown in Fig. 2. In Fig. 6, the core clamp assembly 114 and the wire chuck assembly 30 are omitted in the left-side automatic winding machine 110 to avoid obfuscation. A core/wire feeding machine 116 is arranged at the front side of each automatic winding machine 110 aligned. The core/wire feeding machine 116 comprises a core container 118 and a wire container 120 at the upper and lower positions, respectively, thereof which are not shown in Fig. 7. The core/wire feeding machine 116 travels along a rail 124 (see Fig. 7) mounted on a rack 122 to feed a core and the wire upon being stopped at a predetermined position corresponding to each automatic winding machine 110. A belt conveyer 126 is provided inside the rack 112 at the lower portion of the alignment of the winding machines 110 in parallel with the latter. The belt conveyer 126 is for use in recovering wound produces when each of four winding machines 110 carries out the same winding operation. When these winding machines are applied to wind the wire at different turns, the belt conveyer 126 may be used for container boxes which are for containing the wound products.
Fig. 8 is a plan view of an essential part showing position relationship between one of four automatic winding machines 110 and a core/wire feeding machine 116 stopped at a predetermined position in the automatic winding machine 110. In these figures, the core clamp assembly 114 and the wire chuck assembly 30 are similar to those shown in Fig. 2 and thus a detailed description thereof is omitted here.
The core/wire feeding machine 116 comprises a wire nozzle/cutter member 128. The wire nozzle/cutter member 128 moves with an arm (not shown) holding one of the cores in the oblique direction depicted by a dot-dash line 130 in Fig. 8. The wire nozzle/cutter member 128 is stopped at the position indicated by a broken line where it crosses with the core turning clamp 26 at an acute angle. The wire nozzle/cutter member 128 first feeds a core to the core turning clamp 26 in the stand-by condition. The core turning clamp 26 holds the core being fed thereto. Next, only a wire nozzle (not shown) provided in the wire nozzle/cutter member 128 rises and passes through a cutter portion (not shown). The wire nozzle is inserted into the central aperture 22 of the core to eject upward the leading end 20 of the wire beyond the core. At that moment, the pull chuck 88 of the wire chuck assembly 30 grasps the leading end 20 of the wire and travels upward along the longitudinal guide rail 32 while pulling the wire out of the wire nozzle. The pull chuck rises to a predetermined position and is stopped there. Subsequently, the wire nozzle is lowered and returned downward of the cutter portion. The wire nozzle/cutter member 128 revolves upward or corkscrews up until it reaches the position horizontal to the radial direction of the core depicted by the dot-dash line 130. When the Wire nozzle/cutter member 128 comes to this orientation, the wire contacts with the bottom surface of the core. The pull chuck 88 of the wire chuck assembly 30 pulls the leading end 20 of the wire being contact with the core. A predetermined tension is applied to the wire and, following which the core turning clamp 26 clamps the core together with the tailing end 24 (Fig. 1) of the wire. A cutter (not shown) cut the wire out of the wire nozzle and then the wire nozzle/cutter member 128 revolves downward or corkscrews down under the core to the original position in the core/wire feeding machine 116. This completes feeding of the core and the wire.
The above mentioned four-linkage automatic toroidal coil winding machine is a longitudinal and upright core reversing type. Such winding machine occupies less space for equipment and can be combined into multiple linkage with only one core/wire feeding machine. This means that a limited space can be effectively used for this cost-saving equipment of high performance. In addition, maintenance and operational management can be made easily.
Next, a process for manufacturing the toroidal coil illustrated in Fig. 1 is described with reference to Figs. 9 through 11. Fig. 9 (1A) shows the core 12 not being grasped and turned by the core turning clamp 26 with the tailing end 24 of the wire 18. The core rotating clamp 28 located at its original position shown in Fig. 2 grasps the core 12 fed from the core/wire feeding machine 116 shown in Fig. 8. As mentioned above, the core/wire feeding machine 116 inserts the leading end 20 of the wire 18 into the central aperture 22 of the core 12 from the downward thereof held by the core rotating clamp 28. At that time, the pull chuck 88 is located upward the insertion chuck 90 as shown in Fig. 5. The leading end 20 of the wire 18 extending upward from the central aperture 22 of the core 12 is grasped and raised upward to a predetermined distance by the pull chuck 88 of the wire chuck assembly 30 retracted to the right side of the figure. The core/wire feeding machine 116 pulls up the end of the wire closer to the tailing end 24 in the direction depicted by the arrow 48 in Fig. 2. The core/wire feeding machine 116 then cuts the wire 18 at a predetermined position to provide the tailing end 24. Subsequently, the core 12 and the tailing end 24 of the wire 18 are grasped by the core turning clamp 26 with its concave portion 40 formed in the urethane rubber 38 faced upward as shown in Fig. 3. The wire chuck assembly 30 is then moved upward to apply a predetermined tension to the wire 18. With the tension being applied to the wire, the wire chuck assembly 30 is slightly lowered to loose the wire 18 and the core 12 is away from the core rotating clamp 28. This corresponds to the condition shown in Fig. 9 (1A). At that time, the insertion chuck 90 advances to the same position as the pull chuck 88 to hold the leading end 20 of the wire 18.
The core turning clamp 26 turns the core 12 on the rotation axis 46 shown in Fig. 9 (1A) in the direction depicted by the arrow 44 into the condition illustrated in Fig. 9 (1B). The core 12 turns in such a direction that the wire 18 is wound therearound, so that it is possible to loosely lay the wire 18 on the radially external periphery of the core 12 generally orthogonal to the rotation axis 46. Under such a circumstance, the concave portion 40 formed in the urethane rubber 38 of the core turning clamp 26 is faced downward.
Next, the leading end 20 of the wire 18 is turned counter-clockwise relative to the front of the machine as depicted by an arrow 132 in Fig. 9 (1B). This is achieved by means of half-rotating the wire chuck assembly 30 counter-clockwise from the position shown in Fig. 5 on the axis 104 with the leading end 20 being held by the pull chuck 88 and the insertion chuck 90. In addition, when the wire chuck assembly 30 reversed upside-down from the position shown in Fig. 5 moves downward and is stopped just above the core 12, the pull chuck 88 releases the wire 18 and is retracted. The entire structure of the wire chuck assembly 30 is moved slightly downward with the wire 18 being held only by the insertion chuck 90. Thus, the insertion chuck 90 enables to inserting the leading end 20 of the wire into the central aperture 22 of the core 12.
Before completion of insertion, the pull chuck 88 is moved downward beyond the core 12. The pull chuck 88 is moved ahead to the same position as the insertion chuck 90 to hold the leading end 20 passing through and extending downward from the central aperture 22. The insertion chuck 90 releases the wire 18 and is retracted, following which the wore chuck portion 30 moves down to apply the tension to the wire with the pull chuck 88. This condition is shown in Fig. 9 (1C). The insertion chuck 90 at this moment is located beneath the core 12 while holding the wire 18 at the advanced position as same as the pull chuck 88. The wire 18 is thus tightly laid on the internal periphery of the core 12.
Next, the core 12 is held by the core rotating clamp 28 and then separated from the core turning clamp 26. The core rotating clamp 28 slides on the circular rail 39 (see Fig. 2) by an angle equal to one pitch of winding in the direction (counter-clockwise as seen from the above) depicted by an arrow 134 in Fig. 9 (1C). In this event, the core rotating clamp 28 rotates the core 12 without changing the center thereof. The core 12 after completion of this one-pitch rotation is shown in Fig. 9 (2A).
When the core turning clamp 26 holds the core 12 in the condition shown in Fig. 9 (2A), the core rotating clamp 28 releases the core 12 and is retracted. The core turning clamp 26 then turns in the same direction as shown in Fig. 9 (1A). This results in the core 12 being positioned as shown in Fig. 9 (2B).
Next, the pull chuck 88 of the wire chuck assembly 30 releases the wire 18 and is retracted. The entire structure of the wire chuck assembly 30 is turned over 180° to rotate the leading end 20 of the wire 18 over 180° in the clockwise (as seen from the front) direction as depicted by an arrow 136. The leading end 20 comes to face upward. Subsequently, the insertion chuck 90 moves upward to insert the leading end 20 of the wire into the central aperture 22 from the downward. The pull chuck 88 located above the core 12 is advanced to hold the leading end 20 extending upward from the core 12. Upon grasping the leading end 20, the pull chuck 88 further travels upward to apply the tension to the wire 18 as shown in Fig. 9 (2C). The core rotating clamp 28 holds the core 12 at the condition shown in Fig. 9 (2C). When the core turning clamp 26 is separated from the core 12, the core rotating clamp 28 slides on the circular rail 39 by an angle equal to one pitch of winding in the direction (clockwise) depicted by an arrow 138. As a result, the core 12 is rotated and the core rotating clamp 28 returns to its original position shown in Fig. 2.
Steps (3A), (3B) and (3C) and steps (5A), (5B) and (5C) in Fig. 10 are repetition of steps (1A), (1B) and (1C) in Fig. 9 while steps (4A), (4B) and (4C) in Fig. 10 and steps (14A) and (14B) in Fig. 11 are repetition of steps (2A), (2B) and (2C) in Fig. 9. While steps (5C) through (13C) are not shown in the drawing, the number of winding turns at (13C) is equal to thirteen (accurately, 13. 5 turns). This corresponds to the completion of winding the first layer.
At (14C) in Fig. 11, an additional loop is formed as compared with (13C) in Fig. 10. The number of winding turns is thus equal to fourteen (accurately, 14.5 turns). At (14C) in Fig. 11, the core rotating clamp 28 rotates the core 12 in the same direction (counter-clockwise) as in (13C) in Fig. 1. Accordingly, the wire overlaps the first layer as shown in (15a) in Fig. 11.
The second layer is formed by means of repeating the above mentioned steps, i.e., turning the core, inserting the leading end of the wire into the central aperture, applying the tension to the wire and rotating the core. The process for winding the second layer differs from that for the first layer. More particularly, as shown in (15c) and (17c) in Fig. 11, the core is rotated clockwise after being subjected to the tension downward and is rotated counter-clockwise after being subjected to the tension upward. In figures representing steps after (16b) in Fig. 11, the tailing end 24 of the wire is depicted by the solid line and the last winding of the first layer is depicted by the broken line. Other turns are all omitted from these figures to avoid obfuscation.
While the coil shown in Fig. 1 is double-layered with 26 winding turns (26.5 turns), the present invention is applicable to a coil of three or more layers by means of repeating the steps for preparing the first and the second layers.
According to the above mentioned embodiment of the present invention, rotation of the core on the central axis thereof is performed by the rotating arrangement separate from the arrangement for reversing the core on the diametrical axis thereof. The winding can thus be made with high accuracy at a predetermined pitch even for the lap winding. In addition, all steps can be made automatically only with a simple automatic machine. Another advantage of the present invention is that it is possible to wind the wire on a small core without badly affecting on the insulating layer. Further, the increased number of turns will cause no serious problem by the operational considerations.
According to the above mentioned embodiment, the core clamp assembly consists of separate members, i.e., the core turning clamp and the core rotating clamp for feeding. The grasp claw of the core turning clamp is provided with a concave portion, allowing the tailing end 24 radially outwardly extending from the core to be held without being deformed or curved by the core turning clamp not being inclined. Further, it is possible to shift positively the position where the wire is to be wound by means of rotating the core because the core rotating clamp slides on the circular rail after re-holding the core. This results in the increased yields with less trouble of irregular winding. In addition, the winding pitch can readily be varied even for the lap winding.
The above mentioned four-linkage automatic toroidal coil winding machine is a longitudinal and upright core reversing type. Such winding machine occupies less space for equipment and can be combined into multiple linkage with only one core/wire feeding machine. This means that a limited space can be effectively used for this cost-saving equipment of high performance. In addition, maintenance and operational management can be made easily.
The above mentioned method for winding the wire relies on rotation and turns of the core as well as on turn, insertion and pull of the wire. The same position of the leading end of the wire is repeatedly held and pulled before reversing the orientation. Consequently, the wire is curved at the same position upon being reversed and is deformed due to the work hardening. Such work hardening may be a cause of wire breakage or non-uniform formation of the loop. If the loop is reduced roughly, the wire may further be wriggled to form 8-shaped loops or even a kink may be caused to prevent uniform winding of the wire.
With this respect, to prevent the wire from being wriggled or twisted is the major challenge in manufacturing a toroidal coil. A solution of the problem of wriggle is, as described in the following embodiments, to provide a wire loop supporting member at the opposite side to where the leading end of the wire is turned and to shift the position to be held closer to the tailing end.
Fig. 12 shows another embodiment with a wire loop supporting members provided, in which (A) and (B) show the front and right-hand side view, respectively, of the winding machine. The winding machine illustrated in Fig. 12 corresponds either one of the four winding machines 110 arranged into the four-linkage automatic winding machine shown in Fig. 6. Detailed description of the similar parts will be omitted to avoid redundancy.
An upper loop supporting member 150 and a lower loop supporting member 152 are attached to the rack 112 at the closer side to the core rotating clamp 28. The upper loop supporting member 150 is formed by means of bending a bar (e.g., 5-6 mm in diameter) of metal or resin having a smooth surface at nine or ten points into a desired shape of three-dimension. The lower loop supporting member 152 is formed by means of bending a short bar of metal or resin at two points at obtuse angles.
Movement of the wire 18 and the leading end 20 thereof caused by the wire chuck holder 49 is described with reference to Fig. 12 (A). When the wire is located above an x axis, the wire chuck holder 49 is turned in the direction depicted by the arrow 132 (counter-clockwise) at the left side of a y axis. Consequently, the leading end 20 of the wire faces downward as depicted by the broken dot-dash line and formation of the wire loop is started at the right side of the y axis. When the wire chuck holder 49 is lowered to the position depicted by the solid line, the wire 18 is formed into a large open-loop extending towards the x axis. The portion of the wire 18 extending from the core is abutted to the upper loop supporting member 150 as shown in Fig. 12 (B). When the wire chuck holder 49 is lowered further, the loop of the wire 18 moves along the slope of the upper loop supporting member 150. The loop supporting member 150 thus contributes to provide uniform shape and orientation of the loops.
When the wire chuck holder 49 is lowered to insert the leading end 20 of the wire into the central aperture of the core 12, the closed loop of the wire 18 becomes more flat extending along the x axis as depicted by a dot-dash line 154. Without the upper loop supporting member 150, the wire is much twisted and this closed large loop may be formed into an 8-shape. The loop supporting member 150 abuts the loop of the wire 18 to avoid the loop head to be wriggled. This means that the loop will never be formed into an 8-shape.
The wire chuck bolder again grasps the leading end 20 of the wire beneath the x axis. The closed loop is gradually reduced and away from the loop supporting member 150 to be wound on the core. As mentioned above, the loop supporting member 150 allows the loop to be formed in the uniform formation and orientation. Accordingly, it becomes possible to wind the wire on the core at a desired pitch.
Beneath the x axis, the wire chuck holder 49 is turned in the direction (clockwise) towards the left side of the y axis as depicted by the dot-dash line 136. The loop of the wire 18 is thus formed at the right side of the y axis. The broken line 156 represents the loop of the wire when the wire chuck holder 49 rises to half the height of the rack 112. The loop represented by the broken line is shown in Fig. 12 (A) and the loop of the wire together with the wire chuck holder 49 is shown in Fig. 12 (B). In such a case, the open-loop loop of the wire is abutted to the lower supporting member 152 at or near the free end thereof. The shape and orientation of the loop are also stabilized. The closed loop can thus be reduced in size more smoothly with the lower loop supporting member 152 and it is possible to wind the wire on the core at a desired pitch upon rising the wire chuck holder 49.
The wire chuck holder 49 after completion of round-turn is lowered without changing its orientation with the pull chuck 88 facing ahead. The wire chuck holder 49 is then abutted to an original position detector 158 and release the coil.
Figs. 13 trough 16 are views for use in describing a mechanism and operation of the wire chuck assembly 30 to avoid the wire breakage by means of shifting a position of the leading end 20 of the wire 18 to be held.
Figs. 13 (A) through (G) are views for use in describing operation of the wire chuck holder 49 of the wire chuck assembly 30 shown in Fig. 5.
Fig. 13 (A) shows a condition where the leading end 20 (not shown) of the wire 18 is held only by the pull chuck 88 and the wire chuck holder 49 moves upward. In this state, the L-shaped metal fitting 85 and the screw rod 89 are away from each other at a gap G. Fig. 13 (B) shows a condition where a predetermined tension is applied upwardly to the wire 18 (not shown) to lay the wire on the interior periphery of the core. In this state, the L-shaped metal fitting 85 is abutted to the screw rod 89. Both of the pull chuck 88 and the insertion chuck 90 slide downward until the short shutter member 91 reaches a first detector 95 (shown in Fig. 5).
After the wire chuck holder 49 in the condition shown in Fig. 13 (B) is slightly lowered to return to the condition shown in Fig. 13 (A) with the gap G, the insertion chuck 90 grasps the wire 18 as well and rotates the wire chuck holder 49 downward over 180° on the rotation axis 104 in the direction depicted by the arrow 106 into the orientation represented by the solid line. Fig. 13 (C) corresponds to this condition. The insertion chuck 90 and the pull chuck 88 hold the leading end 20 of the wire 18 apart from each other at the gap G. The wire 18 is curved near the rotation axis 104 and formed into a loop, as described above.
The wire chuck holder 49 downwardly oriented as shown in Fig. 13 (C) is lowered to just above the toroidal core and stopped there temporary. At that time, the pull chuck 88 releases the leading end 20 of the wire and then the wire chuck holder 49 is slightly lowered. In this event, as shown in Fig. 13 (D), the leading end 20 (not shown) of the wire is inserted into the central aperture of the core 12 indicated by the dot line. At the same time, the L-shaped metal fitting 85 of the wire chuck holder 49 abuts a stopper 99 to stop the pull chuck 88. As shown in Fig. 2, the stopper 99 is so provided as to move forward and backward in parallel to the core turning clamp 26. At the advanced position, the tip of the stopper 99 is projected into the longitudinal passage of the wire chuck holder 49. With the L-shaped metal fittings 85 abutted to the stopper 99, the insertion chuck 90 holding the leading end 20 of the wire slightly is lowered and stopped when the tip of the screw rod 89 abuts the L-shaped metal fittings 85. In other words, the gap G between the insertion chuck 90 and the pull chuck 88 is equal to zero as shown in Fig. 13 (E).
The pull chuck 88 again grasps the leading end 20 (not shown) of the wire with no gap G formed and the insertion chuck 90 releases the wire 18 (see Fig. 13 (F)) to retract the stopper 99 from the passage of the wire chuck holder 49. As shown in Fig. 13 (G), the L-shaped metal fittings 85 are separated from the screw rod 89 and the pull chuck 88 returns to a free state with the gap G. The pull chuck 88 is lowered while remaining this condition to reduce the loop of the wire.
Fig. 14 shows the wire chuck holder 49 where downward tension is applied to the wire 18. Fig. 15 shows the wire chuck holder 49 turned upward (upward turn depicted by the arrow 136 in Fig. 9 (2B)) with the leading end 20 of the wire held by the pull chuck 88 and the insertion chuck 90 spaced away at the gap G. Fig. 16 shows a condition where the wire 18 is inserted upward into the central aperture of the core 12 by the insertion chuck 90 and the leading end 20 of the wire is pulled with no gap G just before the pull chuck 88 holds the leading end 20 (corresponding to the condition shown in Fig. 13 (E) facing downwardly).
The wire chuck holder 49 shown in Fig. 16 is in the condition where the pull chuck 88 releases the leading end 20 of the wire after the wire chuck holder 49 rises (not shown) and is stopped just under the core 12.
The above mentioned operation makes it possible to hold by the pull chuck 88 the position of the wire shifted towards the leading end 20 (towards the insertion chuck 90) by an amount equal to the gap G at every time when the leading end 20 of the wire is inserted upwardly or downwardly into the central aperture of the core 12 and held again by the pull chuck 88. In the automatic toroidal coil winding machine according to the above mentioned second embodiment of the present invention, the position of the leading end held by the chuck is shifted by a predetermined amount at every time of re-holding during the repeated process of turning the core, turning the leading end of the wire and insertion of the same into the central aperture of the core. As a result, the position of the wire deformed due to turning is shifted gradually and the work hardening responsible for wire deformation will never be caused. Accordingly, it is possible to manufacture toroidal coils in high yields with no fear of wire breakage upon winding the wire on the core.
Next, described with reference to Figs. 17 and 18 are a method and a device for controlling the tension applied to the wire in an automatic toroidal coil winding machine of the upright type using a technique of turning the core according to the embodiment of the present invention. In the above mentioned toroidal coil winding machine using the technique of core turning, the efficiency of winding can be improved with the reduced cycle time of winding by means of increasing the speed of the wire chuck holder. However, such increased speed of the wire chuck holder also increases the frequency of applying a dynamic tension to the wire with some trouble in applying the tension uniformly to the entire length of wire. As a result, the stress is concentrated at a weak portion or wriggled portion of the wire to cause a local extension of the wire or even a wire breakage. In addition, in the automatic winding machine of the type described, the wire is inserted into the central aperture of the core and the tension is applied to the wire by using the wire chuck assembly traveling upward and downward along the guide rail. This means that the tension applied to the wire depends on the weight of the pull chuck of the wire chuck assembly and the inertia thereof upon traveling. Accordingly, the tension applied to the wire may be fluctuated depending on the longitudinal position of the wire chuck assembly. With this respect, it is necessary to overcome these problems and control the tension applied to the wire when the wire chuck assembly is moved at a high speed to wind the wire on the core.
In the embodiment according to the present invention, as described in conjunction with Fig. 7, the synchronous belt 55 and the servo-motor 53 are used for driving the wire chuck assembly 30 having the pull chuck 88 and the insertion chuck 90 that travels upward and downward along the guide rail 32. In addition, the wire chuck holder 49 of the wire chuck assembly 30 comprises, as described in conjunction with Fig. 5, two shutter members 91 and 93 which are different in length from each other and two tension detectors 95 and 97 corresponding to the respective shutter members. The tension applied to the wire can be controlled by using these components.
Fig. 17 is a flow chart of the operation carried out by the automatic toroidal coil winding machine according to the present invention to control the tension applied to the wire upon winding the wire on the core under tension control. The operation is now described with reference to the drawing.
At step 160 of core/wire feeding shown in Fig. 17, the core 12 (see Fig. 1) fed by the core/wire feeding machine 116 shown in Fig. 7 is held by the core clamp assembly 114 and the wire 18 is passed through the central aperture 22 of the core 12 by using the core/wire feeding machine 116 as described above in conjunction with Fig. 8. The wire chuck holder 49 is oriented to the upward as shown in Fig. 18(a). The pull chuck 88 of the wire chuck holder 49 holds the leading end 20 of the wire and rises to a predetermined position along the guide rail 32. This predetermined distance corresponds to the length of the wire to be wound at a predetermined number of turns and is set by means of supplying predetermined number of drive pulses to the servo-motor 53. When the wire chuck holder 49 stops at the set position, the tailing end of the wire 18 is cut by the core/wire feeding machine 116 at the lower position to complete feeding of wire to the core.
At step 162 in Fig. 17 for turning the core and laying the wire on the external periphery thereof, the core 12 held by the core turning clamp 26 in the core clamp assembly 114 turns, as shown in Figs. 2 and 9, on the rotation axis 46 together with the tailing end 24 of the wire, thereby the wire is laid on the external periphery of the core.
At step 164 in Fig. 17 for turning and inserting the leading end of the wire into the central aperture of the core, the wire chuck holder 49 is turned, as shown in Fig. 18 (b), with the pull chuck 88 holding the leading end 20 of the wire. The pull chuck turned is directed downward and is lowered to the position just above where the core 12 depicted by the dot line 105 in Fig. 7 is held. The wire chuck holder 49 represented by the solid line in Fig. 7 is in the condition where the pull chuck 88 is located at the lower stage and is on the half-way of its downward movement with the wire 18 held. Illustrated is a condition where the wire 18 is formed into a loop above the core 12 and is gradually thrown down. Subsequently, the pull chuck 88 releases the leading end 20 of the wire and the insertion chuck 90 advances to grasp the wire 18. The pull chuck 88 is then retracted towards the longitudinal guide rail 32, which is followed by the slight lowering of the wire chuck holder 49. The leading end 20 of the wire 18 held by the insertion chuck 90 is inserted into the central aperture 22 of the core.
At step 166 in Fig. 17 to close the pull chuck, the tip of the pull chuck 88 again advances towards the core to grasp the leading end 20 of the wire under the core 12. The insertion chuck 90 releases the wire 18 and is retracted back to the guide rail 32. When the pull chuck 88 grasps the leading end 20 of the wire with its tip, the stopper expanded from and retracted to the core turning clamp shown in Fig. 2 forces the pull chuck 88 to the insertion chuck 90. As a result, the gap G between them becomes zero and the position on the wire 18 held by the pull chuck 88 shifts closer to the insertion chuck by the amount equal to the gap G.
At step 168 in Fig. 17 for high-speed coarse positioning, the wire chuck holder 49 grasps the wire 18 with the pull chuck 88 and is lowered at a high speed along the longitudinal guide rail 32. The wire chuck holder 49 is lowered while stretching downward the leading end 20 of the wire. The loop of the wire is reduced in size and finally the wire is straightened. The wire chuck holder 49 stops temporarily just before the tension is applied to the straightened wire. More particularly, under this condition, the extension spring 100 connected to the pull chuck 88 shown in Fig. 18 (b) is not extended yet. This operation is referred to as the high-speed coarse positioning.
At step 170 in Fig. 17 for pulse feed, the drive pulses are supplied to the servo-motor 53 for moving the wire chuck holder 49 by an extremely short distance of, for example, 0.5 mm.
At step 172 in Fig. 17 for turning ON the tension detectors, the downward tension is gradually applied to the wire 18 by means of the continuous pulse feed. The pulses are continuously supplied to the servo-motor 53 until the long shutter member 93 reaches the lower tension detector 97 to turn ON the same. Fig. 18 (b) shows the condition where the long shutter member 93 acts, in which the wire 18 is downwardly directed and the same tension is applied to the wire as is described in conjunction with Fig. 18 (a). The extension spring 100 is extended until the pull chuck 88 rises following the wire 18 and the L-shaped metal fitting 85 is abutted to the adjusting screw rod 89 to slightly raise both the pull chuck 88 and the insertion chuck 90. Assuming that the winding machine applies the constant tension to the wire 18, the actual tension applied to the wire 18 is increased due to the weight of the pull and insertion chucks 88 and 90 as compared with the condition illustrated in Fig. 18(a). Accordingly, the length to be shifted by means of the pulse feed becomes short. This is because that the wire 18 is subjected to the tension equivalent to that caused by the extension spring 100 with the weight of the pull chuck 88 and the insertion chuck 90.
At step 174 in Fig. 17 for returning, the wire chuck holder 49 rises at a predetermined amount to release the tension to the wire after completion of the pulse feed. This operation is referred to as "return."
At step 176 in Fig. 17 for rotating the core, the core rotating clamp 28 moves along the circular rail 39 as shown in Fig. 2 to shift the horizontal position of the core by the amount equal to one pitch of winding.
Subsequently, step 162 is again carried out to turning the core and laying the wire on the external periphery of the core. As shown in Figs 2 and 9 (2A), the core turning clamp 26 in the core clamp assembly 114 turns the core 12 on the rotation axis 46 to wind the wire thereon.
At the subsequent step 164 for turning and inserting the leading end of the wire into the central aperture of the core, the wire chuck holder 49 is turned, as shown in Fig. 9 (2B), with the pull chuck 88 holding the leading end 20 of the wire. The pull chuck turned is directed upward and rises at a high speed along the guide rail 32. The pull chuck 88 moves up to and stopped at the position just under where the core 12 depicted by the dot line 105 in Fig. 7 is held. Subsequently, the pull chuck 88 releases the leading end 20 of the wire to draw it backward and the insertion chuck 90 advances to grasp the wire 18. The wire 18 held by the insertion chuck 90 slightly rises with the wire chuck holder 49 and the leading end 20 of the wire 18 is inserted from the downward into the central aperture 22 of the core.
At step 166 in Fig. 17 to close the pull chuck, the pull chuck 88 grasps the leading end 20 of the wire above the core 12. The insertion chuck 90 releases the leading end 20 of the wire 18 and is retracted backward. When the tip of the pull chuck 88 grasps the leading end 20 of the wire, the stopper expanded from and retracted to the core turning clamp shown in Fig. 2 forces the pull chuck 88 to the insertion chuck 90. As a result, the gap G between them becomes zero and the position on the wire 18 held by the pull chuck 88 shifts closer to the insertion chuck by the amount equal to the gap G.
At step 168 in Fig. 17 for high-speed coarse positioning, the wire chuck holder 49 rises at a high speed and the high-speed coarse positioning is achieved with the servo-motor 53.
At step 170 for pulse feed and at step 172 for turning ON the tension detectors, the pulses are continuously supplied to the servo-motor 53 and the upward tension is gradually applied to the wire 18 until the short shutter member 91 turns ON the first detector 95 shown in Fig. 18. In this event, the wire 18 is subjected to the tension equivalent to that caused by the extension spring 100 from which the weight of the pull chuck 88 and the insertion chuck 90 is subtracted. It is noted that, upon raising the wire chuck holder 49, the long shutter member 93 and the second detector 97 opposite to the long shutter member 93 are prevented from being operated.
At step 174 in Fig. 17 for returning, the wire chuck holder 49 performs the returning operation simultaneously with the downward stretching. Subsequently, the above mentioned steps are repeated for rotating the leading end, shifting the horizontal position of the core, and insertion the wire into the central aperture of the core.
It is possible to improve the accuracy of the high-speed coarse positioning and the tension applied to the wire by means of controlling the servo-motor 53 using a program including a data representing the length of the wire per turn (length of the wire laid on the internal periphery of the core plus that laid on the external periphery thereof) and of reducing an operational distance required for the high-speed coarse positioning in proportion to the number of turns wound on the core. In this event, the first high-speed coarse positioning is count as the first winding or turn and then the number of turns is counted at every time when the first and the second detectors 95 and 97 generate an ON signal.
When the ON signal at the desired count is supplied to complete the return operation, the core clamp assembly 114 releases the core 12 and is lowered with the pull chuck 88 of the wire chuck holder 49 grasping the leading end 20 of the wire. If the winding operation to the core 12 is completed with the pull chuck in the down-facing orientation, the wire chuck holder 49 turns upon being lowered. The wire chuck holder 49 is then abutted to the original position sensor 125 as depicted by the broken line beneath the movable rack 112 in Fig. 7 to fall the core 12 already wound with the wire into a discharger 126.
While the above mentioned description has not referred to the extension spring 102, it is apparent that the tension applied to the wire upon raising and lowering the wire chuck holder 49 can be adjusted by means of adequately setting the gap G as well as the difference in length between the long shutter member 93 and the short shutter member 91.
In addition, while the above mentioned embodiments have thus been described in conjunction with the wire chuck holder 49 having the pull chuck 88 and the insertion chuck 90, the above mentioned method for controlling the tension can be applied to the wire chuck holder having no insertion chuck 90.
As mentioned above, according to the embodiments of the present invention, it is possible to wind the wire on the core using one extension spring in the toroidal coil winding machine of the upright type without being affected by the weight of the pull chuck. As a result, it becomes possible to provide toroidal coils having good appearance with less variation in the external dimension and in the length of the lead wire.
Furthermore, in the method and the apparatus for controlling the tension , to pull the wire and to apply the tension to the wire are made by means of operating at two stages the pull chuck for repeatedly winding the wire on the core and the wire chuck holder where the insertion chuck is implemented, which results in the reduced time for winding steps. In addition, approximately equal amount of stationary constant tension is applied to the wire and a wire-breakage preventing device is implemented for changing the position on the wire to be held by the pull chuck, so that there is no fear of trouble in winding or in the wire itself such as the breakage.

Claims

A method for winding a toroidal coil comprising the steps of
(a) inserting one end (20) of a wire insertion into a core (12) having a central aperture (22);

(b) grasping and holding again the wire (18) to pull the same;

(c) turning the core (12) and another end (24) of the wire (18) in a diametrical direction (44) of the core perpendicular to a radial direction;

(d) turning the one end (20) of the wire (18) and inserting the one end (20) of the wire (18) into the core (12);

(e) rotating the core (12) at a desired angle (134) in one direction about a central axis of the core (12);

(f) shifting the one end (20) of the wire (18) towards the other end (24) of the wire (18).
A method according to claim 1, wherein
the one end (20) of the wire (18) inserted into the central aperture (22) of the core (12) has a predetermined length and extends along the axial direction of the core (12) while the other end (24) of the wire (18) is radially extended at a predetermined length;

wherein in the step (c) the core (12) is turned, thereby laying the wire (18) on the other surface of the core (12) and an external periphery thereof;

wherein in step (e) the core (12) is rotated independent of the turning

wherein further (g) the core (12) is grasped again to turn the core (12),

(h) the one end (20) of the wire (18) is again inserted into the central aperture (22) of the core (12)

(i) the one end (20) of the wire (18) being extended and a tension being applied to the wire (18)

(j) the core (12) is rotated back at the desired angle (138) in an other direction opposite to said one direction and wherein the steps (a) to (j) are repeatedly carried out to form an odd layer of the winding.
A method according to claim 2,
further comprising the steps of:
(k) carrying out the steps (g) to (j),

(l) repeating the steps (g) to (i) and then

(m) rotating the core (12) to rotate the core (12) at the desired angle (134) in the one direction

(n) repeatedly carrying out the steps (k) to (m) to form an even layer of the winding.
A method according to one of claims 1 to 3,
wherein a tension is applied to the wire (18) passed into the central aperture (22) of the toroidal core (12) by
(b1) supporting the wire (18) at both sides,

(b2) pulling the end of the wire (18) passed through the central aperture (22) of the toroidal core (12) in the direction of a central axis of the toroidal core (12),
and performing step (c) to lay the wire (18) on an external periphery of the toroidal core (12).
A machine for winding a toroidal coil comprising:
a turning clamp portion (26) for holding the core (12) together with one end of the wire (18) as well as for turning the core (12) upside-down;

a rotary clamp portion (28) for holding the core (12) as well as for travelling along a circular guide rail (39) on the axis of the core (12) to turn the core circumferentially; the turning clamp portion (26) and the rotary clamp portion (28) forming a core clamp portion (114); and

a wire chuck assembly (30) for inserting the other end of the wire into a central aperture of the core (12) and for applying a predetermined tension to the wire (18) to wind the wire (18) on the core (12) trough a combination of a turning operation and a rotating operation to the core (12), whereby turning of the core (12) is made independent of rotation of the core (12).
A machine as claimed in claim 5, wherein each of said turning clamp portion (26) and said rotary clamp portion (28) comprises a pair of grasping portions (34, 36, 58, 60), and a concave portion is formed for receiving a part of the core (12), the concave portion (40) being formed in either one of the grasping portions provided in said turning clamp portion (26).
A machine as claimed in claim 5 or 6, comprising:
a plurality of core clamp portions (114) arranged at a desired height;

wherein the wire chuck assembly (30) is slidable on an elongated rail (32) extending up to down,

the wire chuck assembly being arranged at one side of the core clamp portions (114)

the plurality of core clamp portions (114) being aligned such that they are adjacent to each other in the same orientation; and

a single core wire feeding machine (116) which moves in parallel to the alignment of the core clamp portions (114) towards the other side of the core clamp portions (114).
A machine according to one of claims 4 to 6,
wherein the wire chuck assembly (30) comprises a chuck holder (49) which is movable in an insertion and pull direction as well as rotatable, a pull chuck (88) and an insertion chuck (90) being provided for independently grasping the wire (18) at sides, the pull chuck (88) being aligned closer to the head of the chuck holder (49) and being apart from the insertion chuck (90), the pull chuck (88) and the insertion chuck (90) being independently slidable; and

further comprising a stopper (99) arranged near the core (12), the stopper (99) being freely projected and withdrawn without interfering the movement of the chuck holder (49), whereby the pull chuck (88) and the insertion chuck (90) away from each other at a free condition grasp one end of a wire before being inserted, the pull chuck (88) again grasping the one end of the wire inserted after the stopper (99) engages the pull chuck (88) and the pull chuck (88) abuts to the insertion chuck (90).
A machine according to claim 8 further comprising:
a servo-motor (53) mounted at a top of a longitudinal guide rail (32) elongated upwardly;

a belt (55) driven by said servo-motor (53);

the wire chuck holder (49) integrally being formed with said belt (55); and

the core clamp portion (114) being provided at half the height of said guide rail (32),

the wire chuck holder (49) having the slidable pull chuck (88) for high-speed positioning with the servo-motor (53) along the guide rail (32) in the up-and-down direction; the wire chuck holder (49) being turned and reciprocated for alternatively pulling one end of the wire upward and downward; and

an extension spring (100) so disposed as to connect the pull chuck (88) and the wire chuck holder (49) at the head of the wire chuck holder (49);

two shutter members (91, 93) projected from the insertion chuck (49) at the opposite side of the extension spring (100) and the pull chuck, the shutter members being different in length from each other; and

two tension detectors (95, 97) connected to the shutter members disposed on the wire chuck holder.