JP4945105B2 - Multi-layer coil winding method - Google Patents

Description

  The present invention relates to a multilayer coil and a winding method of the multilayer coil.

  When one wire rod is aligned and wound on a bobbin that is a winding jig, for example, a bobbin having a quadrilateral cross section, the wire is fed by the diameter of the wire rod on one of the four surfaces. It is common. In this case, feeding is not performed on the other three surfaces.

  When the wire is wound up to the end of the core and the wire is wound on the upper layer, the winding direction of the lower and upper layers is reversed on the surface where the wire is fed, as shown in FIG. The hatched portion is an intersection where the lower and upper wire rods intersect. In this way, the wire is doubled on the surface where the wire is fed and the lower and upper layers intersect (hereinafter referred to as “wire feed surface”) (see, for example, Patent Document 1). Note that, on the surface other than the wire feeding surface, the groove between the adjacent wire rods becomes a guide groove for the upper wire rod, so that the wire rods do not intersect and the wire rods do not double.

  Next, the case where two wires are aligned and wound in parallel on a bobbin having a quadrangular cross section of the core will be described with reference to FIG. In this case, on the wire feeding surface, which is one of the four surfaces, the wire is fed by two wires (1). At the end of the wire feeding surface, the wire is wound so as to run up to the upper layer with a gap corresponding to 0.5 wires (2). Then, the upper wire is fed by two wires in the direction opposite to the winding direction of the lower wire (3). In this way, even when two wires are wound in an aligned manner, an intersection where the lower layer and the upper layer of the wire intersect is generated.

At this time, the hatched portion shown in FIG. 14A is in a state where the wire is wound in a triple manner. Therefore, the bulge in the outer diameter direction becomes large on the wire rod feeding surface. Similarly, in the case where three and four wire rods are aligned and wound in parallel on a bobbin having a quadrangular cross section as shown in FIGS. 14B and 14C, The shaded portion is in a state in which the wire is wound three times.
JP-A-8-203720

  In this way, when two or more wires are aligned and wound in parallel, unlike the case where one wire is aligned and wound, the wire feed surface has an intersection where the wires are wound three times. To do. Therefore, there is a problem that the outer diameter of the coil becomes large.

The present invention has been made in view of the above problems, and in the case where two or more wires are aligned and wound in parallel with a core having a polygonal cross section, the wire feed surface faces in the outer diameter direction of the core. bulge and to provide a method of winding increases becoming a not multi-layer coil.

The present invention is a winding method for a multi-layer coil in which n- wires (n is an integer of 2 or more) are aligned and wound around a core having a polygonal cross section, and the n-wires are wound on the core. Winding at the same time , apply the feed of n wires while the wire goes around the core, and at the end of at least one of the surfaces to which the feed is applied, 2 of the wires of the n wires The present invention is characterized in that the arrangement of the twisted wire rods is replaced with the wire rod of the book.

  In the present invention, at the end of the wire feed surface, the two wire rods are twisted to change the arrangement of the wire rods. Therefore, according to the present invention, the bulge of the wire in the outer diameter direction is prevented on the wire feed surface, and a compact multilayer coil can be obtained.

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

(Embodiment 1)
A multilayer coil 100 according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a multilayer coil 100 in which a wire is wound around a winding core, where (a) is a front view, (b) is a plan view, (c) is a rear view, and (d) is a bottom view. FIG. FIG. 2 is a diagram illustrating a winding method at the core end of the multilayer coil 100. The arrows in the figure indicate the winding direction. Moreover, about FIG. 2, only the wire relevant to description is shown in figure, and other wire is not shown in figure.

  The multilayer coil 100 is a bobbin 1 in which wires are wound in multiple layers. The bobbin 1 includes a winding core 2 around which a wire is wound, and flanges 3 provided coaxially with the winding core 2 on both sides of the winding core 2. The core 2 has a quadrangular cross section, and two wire rods 4A and 4B having substantially the same wire diameter are wound around the core 2 in parallel. The wire feed surfaces are two surfaces, a front surface 2a and a back surface 2c, which are two opposing surfaces, and the wire material is fed by the diameter of the wire material (one wire) on each surface. The other two planes 2b and bottom 2d are not fed. Thereby, when winding a wire to the core 2 in multiple layers, the winding direction of the lower layer and the upper layer of the wire is reversed between the front surface 2a and the back surface 2c. As described above, the multilayer coil 100 has the intersecting portion 5 where the lower layer and the upper layer of the wire intersect each other on the front surface 2a and the back surface 2c.

  In addition, the multilayer coil 100 is twisted at the end of the back surface 2c by two wires, a wire 4A that runs from the lower layer to the upper layer, and a wire 4B in which the winding direction of the winding is opposite to that of the lower layer. It has a twisted portion 6 in which the arrangement is changed. Since the twisted portion 6 is generated when the two wires 4A and 4B are twisted and intersected, the wires are doubled. In addition, after the wires 4A and 4B form the twisted portion 6 at the end of the back surface 2c, one wire 4A rides between the collar 3 and the lower wire, and the other wire 4B intersects with the lower wire and It is wound in a groove between wires. In this way, the twisted portion 6 and the intersecting portion 5 at the end of the back surface 2c are double and are not rolled up in triplicate. It should be noted that even at the front 2a end, the intersecting portion 5 is double and is not rolled up three times.

Next, a winding method of the multilayer coil 100 will be described with reference to FIG. (A), (e), (i) is a front view, (b), (f) are plan views, (c), (g) are rear views, and (d), (h) are bottom views. In addition, back view (c), (g) shows the state seen through the bobbin 1 from the front for convenience of explanation.
(1) Two wires 4A and 4B are started to be wound in parallel from the same surface of the core 2 having a quadrangular cross section.
(2) As shown in FIGS. 2 (a) to 2 (d), one wire is fed on the front surface 2a and the back surface 2c, and no feed is applied on the flat surface 2b and the bottom surface 2d.
(3) At the front 2a end, as shown in FIG. 2 (e), the wire 4A on the inner side of the winding core feeds one wire to the gap corresponding to 1.5 wires, and the core 2 The wire 4B on the outer side of the core is wound around the gap of 0.5 wires between the wire 4A and the flange 3 and wound on the upper layer.
(4) On the next plane 2b, as shown in FIG. 2 (f), the wires 4A and 4B are wound around the end of the core 2 without feeding.
(5) On the next back surface 2c, as shown in FIG. 2 (g), the wires 4A and 4B are twisted and wound, and the arrangement of the wires 4A and 4B is switched. Specifically, the wire rod 4A on the inner side of the winding core rides on a gap corresponding to 0.5 wires between the lower wire rod and the flange 3, and is wound on the upper layer. Further, the wire 4B outside the winding core is wound in a direction opposite to the winding of the lower layer, and forms a twisted portion 6 by crossing the wire 4A, and also crosses the lower wire and crosses the lower layer. It is wound in a groove between adjacent wound wires. As described above, the twisted portion 6 generated by twisting the wires 4A and 4B and the intersecting portion 5 generated by intersecting the wire 4B and the lower layer wire exist at the end of the back surface 2c. In both the twisted portion 6 and the intersecting portion 5, the wire rods are doubled and are not rolled up in triplicate. Note that the arrangement of the wires 4A and 4B referred to here is switched as shown in FIG. 2 (g), in the lower layer, the arrangement of the wires is 4A, 4B, 4A, 4B,. In contrast to the arrangement, it means that the upper layer is opposite to the lower layer arrangement of 4B, 4A, 4B, 4A,.
(6) On the next bottom surface 2d, as shown in FIG. 2 (h), the wire rods 4A and 4B are guided and wound in the groove between the adjacent lower windings without being fed.
(7) On the next front surface 2a, as shown in FIG. 2 (i), the wire rods 4A and 4B are wound in a direction opposite to the feeding direction of the lower wire rod. Thus, in the front surface 2a, the lower layer and the upper layer of the wire intersect. However, the intersecting portions 5 are both double and are not rolled up in triplicate.

  In the multilayer coil 100 described above, the wire feeding surface is the front surface 2a and the back surface 2c, but the wire feeding surface can be set to any two surfaces of the winding core. Moreover, although the cross section of the winding core is a quadrangular shape, other polygonal shapes may be used.

  At the beginning of winding, as shown in FIG. 3 (a), on the wire feed surface, the wire feed portion (the wire 1 in the multilayer coil 100) is fed to the end of the core 2, as shown in FIG. It is necessary to provide protrusions 7). Further, instead of providing the protrusion, as shown in FIG. 3B, an inclined notch 8 may be provided in the collar portion 3, and the wire rod may be held by the notch 8.

  As described above, the multi-layer coil 100 feeds one wire on two arbitrary surfaces, and at the end of the core 2, the wire 4 </ b> A runs from the lower layer to the upper layer, and the winding direction of the winding is the lower layer. The two wire rods of the wire rod 4B opposite to the wire rod are twisted to change the arrangement of the wire rods. Thereby, the multilayer coil 100 is prevented from bulging of the wire in the outer diameter direction on the wire feed surface, and becomes a compact multilayer coil.

(Embodiment 2)
A multilayer coil 200 according to the second embodiment of the present invention will be described with reference to FIG. 4A and 4B are diagrams showing a winding method at the core end of the multilayer coil 200, where FIGS. 4A and 4E are front views, FIG. 4B and FIG. ), (G) are rear views, and (d), (h) are bottom views. In addition, back view (c), (g) shows the state seen through the bobbin 1 from the front for convenience of explanation. Further, only the wire related to the description is shown, and the other wires are not shown.

  The difference between the multilayer coil 200 and the multilayer coil 100 is that the number of wires wound around the winding core 2 is three (4A, 4B, 4C). There are three wire rod feed surfaces, a front surface 2a, a flat surface 2b, and a back surface 2c, and the wire rod is fed by one wire on each surface. The other bottom surface 2d is not fed. Thereby, when winding a wire to the winding core 2 in multiple layers, the winding direction of the lower layer and the upper layer of the wire is reversed on the front surface 2a, the plane 2b, and the back surface 2c. Thus, the multilayer coil 200 has the intersection 5 where the lower layer and the upper layer of the wire intersect each other on the front surface 2a, the flat surface 2b, and the back surface 2c. The multilayer coil 200 is twisted at the ends of the flat surface 2b and the back surface 2c with two wires, a wire rod that runs from the lower layer to the upper layer, and a wire rod whose winding direction is opposite to that of the lower layer wire, It has the twist part 6 in which the arrangement | sequence of a wire is switched.

Next, a winding method of the multilayer coil 200 will be described.
(1) Three wires 4A, 4B, and 4C are started to be wound in parallel from the same surface of the core 2 having a quadrangular cross section.
(2) As shown in FIGS. 4A to 4D, one wire is fed on the front surface 2a, the plane 2b, and the back surface 2c, and no feed is applied on the bottom surface 2d.
(3) At the front 2a end, as shown in FIG. 4 (e), the wires 4A and 4B on the inner side of the winding core are wound by feeding one wire to the gap for 2.5 wires. While being wound around the core 2, the wire rod 4C on the outer side of the winding core rides on a gap corresponding to 0.5 wires between the wire rod 4B and the flange portion 3 and is wound on the upper layer.
(4) On the next plane 2b, as shown in FIG. 4 (f), the wire 4A is wound by feeding one wire, and the wire 4B and the wire 4C are twisted and wound to form the wire 4B. The 4C array is swapped. Specifically, the wire rod 4 </ b> B on the inner side of the winding core rides on a gap corresponding to 0.5 wires between the lower wire rod and the flange 3 and is wound on the upper layer. Further, the wire rod 4C outside the winding core is wound in the direction opposite to the winding of the lower layer, and forms a twisted portion 6 by intersecting the wire 4B, and also intersects with the lower layer wire 4A. The wire is wound in a groove between adjacent wires wound around the wire. As described above, at the end of the flat surface 2b, the twisted portion 6 generated by twisting the wires 4B and 4C and the intersecting portion 5 generated by the intersection of the wire 4C and the lower wire 4A exist. In both the twisted portion 6 and the intersecting portion 5, the wire rods are doubled and are not rolled up in triplicate.
(5) On the next back surface 2c, as shown in FIG. 4 (g), the wire 4C is wound by feeding one wire, and the wire 4A and the wire 4B are twisted and wound to form the wire 4A. The 4B array is swapped. Specifically, the wire rod 4A on the inner side of the winding core rides on a gap corresponding to 0.5 wires between the lower wire rod and the flange 3, and is wound on the upper layer. Further, the wire 4B outside the winding core is wound in a direction opposite to the winding of the lower layer, and forms a twisted portion 6 by intersecting the wire 4A, and also intersects with the lower layer of the wire 4A. And 4C. Thereby, the arrangement | sequence of the wire rod of a lower layer and an upper layer interchanges. As described above, at the end of the back surface 2c, the twisted portion 6 generated by twisting the wire rods 4A and 4B and the intersecting portion 5 generated when the wire rod 4B intersects the lower wire rod exist. In both the twisted portion 6 and the intersecting portion 5, the wire rods are doubled and are not rolled up in triplicate.
(6) On the next bottom surface 2d, as shown in FIG. 4 (h), the wires 4A, 4B, and 4C are guided and wound in the grooves between adjacent windings in the lower layer without being fed.
(7) On the next front surface 2a, as shown in FIG. 4 (i), the wires 4A, 4B, and 4C are wound in a direction opposite to the feeding direction of the lower layer wire. Thus, in the front surface 2a, the lower layer and the upper layer of the wire intersect. However, the intersecting portions 5 are both double and are not rolled up in triplicate.

  In the multilayer coil 200 described above, the wire feeding surface is the front surface 2a, the flat surface 2b, and the back surface 2c, but the wire rod feeding surface can be set to any three surfaces of the winding core. Further, although the cross section of the core is a quadrangular shape, it may be a polygonal shape of a triangular shape or more.

  At the beginning of winding, it is necessary to provide a wire feed projection at the end of the core 2 in the same manner as the multilayer coil 100 so that the wire to be wound does not move on the feeding surface. Moreover, you may provide the notch which inclined in the collar part 3 instead of providing a protrusion.

  As described above, the multilayer coil 200 feeds one wire on any three surfaces, and climbs from the lower layer to the upper layer at the core end portions of two of the three surfaces to be fed. The arrangement of the wire rods is changed by twisting two wire rods of the wire rod and the wire rod whose winding direction is opposite to that of the lower layer wire rod. Thereby, the multilayer coil 200 is prevented from bulging of the wire in the outer diameter direction on the wire feed surface, and becomes a compact multilayer coil.

(Embodiment 3)
With reference to FIG. 5, the multilayer coil 300 which is Embodiment 3 of this invention is demonstrated. FIGS. 5A and 5B are diagrams showing a winding method at the winding core end portion of the multilayer coil 300. FIGS. 5A, 5E, and 5I are front views, FIGS. 5B and 5F are plan views, and FIG. ), (G) are rear views, and (d), (h) are bottom views. In addition, back view (c), (g) shows the state seen through the bobbin 1 from the front for convenience of explanation. Further, only the wire related to the description is shown, and the other wires are not shown.

  The difference between the multilayer coil 100 and the multilayer coil 200 in the multilayer coil 300 is that the number of wires wound around the winding core 2 is four (4A, 4B, 4C, 4D). The wire feed surfaces are all the surfaces (front surface 2a, flat surface 2b, back surface 2c, and bottom surface 2d) of the core 2, and the wire is fed by one wire on each surface. Thereby, when winding a wire to the winding core 2 in multiple layers, the winding direction of the lower layer and the upper layer of the wire is reversed on all surfaces. As described above, the multilayer coil 300 has the intersecting portion 5 where the lower layer and the upper layer wire intersect each other on all surfaces of the core 2. In addition, the multilayer coil 300 has two wires, that is, a wire rod that runs from the lower layer to the upper layer and a wire rod whose winding direction is opposite to that of the lower layer wire at the ends of the flat surface 2b, the back surface 2c, and the bottom surface 2d. It has a twisted portion 6 that is twisted and the arrangement of the wires is changed.

  Since the winding method of the multilayer coil 300 is the same as the winding method of the multilayer coil 100 and the multilayer coil 200, description thereof is omitted.

  In the above Embodiments 1-3, the case where the number of wires is 2 to 4 has been shown. However, the present invention is not limited to this, and even when there are five or more coils, the cross-sectional shape of the core is made pentagonal or more. Therefore, consider the case where the number of wires is n (n is an integer of 2 or more), and the n wires are aligned and wound around a core having an N-shaped cross section (N ≧ n). In this case, winding is performed by feeding one wire rod on any n faces of the N faces of the winding core. And two of the wire rod that runs from the lower layer to the upper layer and the wire rod in which the winding direction of the winding is opposite to that of the lower layer wire at each of the n-1 surface end portions of the n surfaces. Twist the wires to change the arrangement of the wires. By winding n wire rods in this way, the n wire rod feed surfaces prevent the wire rods from bulging in the outer diameter direction, and the resulting multilayer coil is compact.

(Embodiment 4)
Next, a multilayer coil 400 according to the fourth embodiment of the present invention will be described with reference to FIGS. 6 is a front view of the multilayer coil 400 showing a state in which the wire is wound around the core, and FIG. 7 is a diagram showing a winding method at the core end of the multilayer coil 400. The arrows in the figure indicate the winding direction. Moreover, about FIG. 7, only the wire relevant to description is shown in figure, and other wire is not shown in figure.

  The multilayer coil 400 is formed by winding two wire rods 4A and 4B having substantially the same wire diameter on a winding core 2 having a quadrangular cross section in parallel. The configuration of the bobbin 1 is the same as that of the multilayer coil 100, and an inclined notch 8 that holds the wire material at the beginning of winding is provided in the flange portion 3.

  The wire rod feeding surface is one surface of the front surface 2a, and the wire rod is fed by two wires on the front surface 2a. The other three sides do not feed. Thereby, when winding a wire around the winding core 2 in multiple layers, the winding direction of the lower layer and the upper layer of the wire is reversed on the front surface 2a. Thus, the multilayer coil 400 has the intersection part 5 where the lower layer and the upper layer wire intersect each other on the front surface 2a.

  The multilayer coil 400 has a twisted portion 6 at the end of the front surface 2a where the two wire rods 4A and 4B running from the lower layer to the upper layer are twisted and the arrangement of the wire rods is switched. Since the twisted portion 6 is generated when the two wire rods 4A and 4B are twisted and crossed, the wire rod is doubled. Further, since the twisted portion 6 is formed close to the end portion of the core 2, it does not interfere with the adjacent wire. The wire rods 4A and 4B riding on the upper layer are wound by applying a feed in the opposite direction to the lower wire rod at the front surface 2a after turning the end of the core 2 3/4 without feeding. At this time, since the lower twist portion 6 is positioned near the end of the core 2, the wires 4 </ b> A and 4 </ b> B do not interfere with the twist portion 6. Therefore, the lower layer and the upper layer of the wire are not triple-wrapped.

Next, a winding method of the multilayer coil 400 will be described with reference to FIG. (A), (e), (f) is a front view, (b) is a plan view, (c) is a rear view, and (d) is a bottom view. The rear view (c) shows a state seen through the bobbin 1 from the front for convenience of explanation.
(1) Two wires 4A and 4B are started to be wound in parallel from the same surface of the core 2 having a quadrangular cross section.
(2) As shown in FIGS. 7A to 7D, feed for two wires is applied on the front surface 2a, and no feed is applied on the flat surface 2b, the back surface 2c, and the bottom surface 2d. In addition, at the end of the core 2, the wire is wound leaving a gap corresponding to 0.5 wires.
(3) At the end portion of the front surface 2a that is the wire rod feeding surface, as shown in FIG. 7E, the wire rods 4A and 4B that run from the lower layer to the upper layer are twisted and the arrangement of the wire rods is switched. Specifically, the wire rod 4A on the inner side of the winding core rides on a gap corresponding to 0.5 wires between the lower wire rod and the flange 3, and is wound on the upper layer. Further, the wire 4B outside the winding core is wound in a direction opposite to the winding of the lower layer, and forms a twisted portion 6 by crossing the wire 4A, and also crosses the lower wire and crosses the lower layer. It winds on the groove between the adjacent wires that have been wound. Thus, the twisted part 6 produced by twisting the wire 4A, 4B and the intersecting part 5 produced by intersecting the wire 4B and the lower wire exist at the end of the front surface 2a. In both the twisted portion 6 and the intersecting portion 5, the wire rods are doubled and are not rolled up in triplicate.
(4) In the next flat surface 2b, back surface 2c, and bottom surface 2d, the wires 4A and 4B are not fed, and the gap between the lower layer and the flange portion 3 is 0.5 minutes between the adjacent windings in the lower layer. It is guided to the groove and wound. Illustration is omitted.
(5) On the next front surface 2a, as shown in FIG. 7 (f), the wire rods 4A and 4B are fed and wound in the direction opposite to the feeding direction of the lower wire rod. At this time, since the twisted portion 6 is formed close to the end of the core 2, the wires 4 </ b> A and 4 </ b> B do not interfere with the twisted portion and are wound only crossing with the underlying wire. Accordingly, the intersecting portion 5 between the lower layer and the upper layer is both double and is not wound in triplicate.

  In the multilayer coil 400 described above, the wire feeding surface is the front surface 2a, but the wire feeding surface can be set to any one surface of the winding core. Moreover, although the cross section of the winding core is a quadrangular shape, other polygonal shapes may be used.

  As described above, the multilayer coil 400 feeds two wires on an arbitrary surface, and twists the two wires that run from the lower layer to the upper layer at the end of the surface to be fed. The arrangement of Thereby, the multilayer coil 400 is prevented from bulging of the wire in the outer diameter direction on the wire feed surface, and becomes a compact multilayer coil.

(Embodiment 5)
Next, with reference to FIG. 8, the multilayer coil 500 which is Embodiment 5 of this invention is demonstrated. FIG. 8 is a diagram showing a winding method at the core end of the multilayer coil 500, where (a) and (e) are front views, (b) are plan views, (c) are rear views, and (d). Is a bottom view. The rear view (c) shows a state seen through the bobbin 1 from the front. Further, only the wire related to the description is shown, and the other wires are not shown.

  The difference between the multi-layer coil 500 and the multi-layer coil 400 is that the number of wires wound around the winding core 2 is a total of four sets (4A, 4B, 4a, 4b) of two sets of two wires. The wire feed surfaces are two surfaces, a front surface 2a and a back surface 2c, which are opposed to each other, and the wire is fed by two wires on each surface. The other two planes 2b and bottom 2d are not fed. Thereby, when winding a wire to the core 2 in multiple layers, the winding direction of the lower layer and the upper layer of the wire is reversed between the front surface 2a and the back surface 2c. As described above, the multilayer coil 500 has the intersecting portion 5 where the lower layer and the upper layer wire intersect each other on the front surface 2a and the back surface 2c. In addition, the multilayer coil 500 has a twisted portion 6 at the end portions of the front surface 2a and the back surface 2c where two wire rods that run from the lower layer to the upper layer are twisted and the arrangement of the wire rods is switched.

Next, a winding method of the multilayer coil 500 will be described with reference to FIG.
(1) Two sets of two wires 4A, 4B, 4a, and 4b are started to be wound in parallel from the same surface of the core 2 having a quadrangular cross section.
(2) As shown in FIG. 8, feed for two wires is applied on the front surface 2a and the back surface 2c, and no feed is applied on the flat surface 2b and the bottom surface 2d. Further, at the end of the core 2, the wire rod 0.5 is wound while leaving a gap of the text.
(3) At the end of the front surface 2a that is the wire feed surface, as shown in FIG. 8A, the wire rods 4A and 4B inside the winding core are wound by feeding the two wire rods. Also, the two wire rods 4a and 4b outside the core are twisted when the lower wire rods 4A and 4B are laid, and the arrangement of the wire rods is switched. The specific winding method of the wires 4a and 4b is the same as the winding method of the twisted portion 6 in the multilayer coil 400.
(4) On the next plane 2b, as shown in FIG. 8B, 4A, 4B, 4a, 4b are wound around the end of the core 2 without feeding.
(5) On the back surface 2c, which is the next wire rod feeding surface, as shown in FIG. 8C, when the lower two wire rods 4A and 4B ride on the upper layer from the lower layer, the arrangement of the twisted wire rods is switched. Further, the upper two wire rods 4a and 4b are wound by feeding the two wire rods opposite to the winding direction of the lower layer. The specific winding method of the wires 4A and 4B is the same as the winding method of the twisted portion 6 in the multilayer coil 400.
(6) On the next bottom surface 2d, as shown in FIG. 8D, the wires 4A, 4B, 4a, and 4b are guided and wound in the grooves between adjacent windings in the lower layer without feeding. The
(7) On the next front surface 2a, as shown in FIG. 8E, the wires 4A, 4B, 4a, and 4b are fed and wound in the direction opposite to the feeding direction of the underlying wire. At this time, since the twisted portion 6 of the wires 4a and 4b is formed close to the end of the core 2, the wires 4A and 4B do not interfere with the twisted portion and intersect only with the underlying wire. Winded. Accordingly, the intersecting portion 5 between the lower layer and the upper layer is both double and is not wound in triplicate.

  In the above fourth and fifth embodiments, the case where the number of wires is one set and two sets of two wires has been shown. However, the present invention is not limited to this, and is possible even when the number of sets of two lines is three or more, that is, six or more. For example, when there are three sets of two wires, winding may be performed by feeding two wires on three sides of the four sides of the core, and when there are four sets of two wires. Can be wound by feeding two wires on all surfaces of the core 4 surface. In this case, by twisting the two wire rods that run from the lower layer to the upper layer at the end of the wire rod feed surface, and changing the arrangement of the twisted wire rods, the lower layer, the upper layer, and the intersection are doubled, Absent.

  Furthermore, when winding five or more sets of two wires, the cross-sectional shape of the core may be a pentagon or more. Accordingly, a case is considered where the number of wire rods is n pairs of n wires (n is an integer of 1 or more), and the 2n wire rods are aligned and wound around a core having an N-shaped cross section (N ≧ n). In this case, winding is performed by feeding two wire rods on any n surfaces of the N surfaces of the core. Then, at the n surface end portions, the two wire rods that run from the lower layer to the upper layer are replaced with the twisted wire rods. By winding 2n wire rods in this manner, the n wire rod feed surfaces prevent the wire rods from bulging in the outer diameter direction, and the resulting multilayer coil is compact.

(Embodiment 6)
Next, with reference to FIG. 9, the multilayer coil 600 which is another aspect of Embodiment 5 is demonstrated. FIG. 9 is a diagram showing a winding method at the core end of the multilayer coil 600, (a) and (f) are front views, (b) are plan views, (c) and (d) are rear views, (E) is a bottom view. The rear views (c) and (d) show the state seen through the bobbin 1 from the front for convenience of explanation. Further, only the wire related to the description is shown, and the other wires are not shown.

  The difference between the multilayer coil 600 and the multilayer coil 500 is that the surface of the winding core of each of the two pairs of wire rods 4A and 4B and the wire rods 4a and 4b is the same surface of the winding core in the multilayer coil 500. On the other hand, the multilayer coil 600 has a different surface of the winding core.

  The wire rods 4A and 4B and the wire rods 4a and 4 are simultaneously wound from the opposed front surface 2a and back surface 2c, respectively. (A) and (d), (b) and (e), and (c) and (f) shown in FIG. 9 respectively illustrate opposing surfaces at the same time. The wire feed surfaces are two surfaces, a front surface 2a and a back surface 2c, which face each other, and the wire material is fed for two wires. The other two planes 2b and bottom 2d are not fed.

  As can be seen from FIG. 9, even when two sets of two wires (4A, 4B and 4a, 4b) are started from different surfaces of the core, respectively, the same configuration as the multilayer coil 500 starting from the same surface is used. A multilayer coil can be obtained.

  That is, in the case where 2n wires (n is an integer of 2 or more) wire rods are aligned and wound around a core having an N-shaped cross section (N ≧ n), n sets of two wire rods are n pieces having different cores. It is possible to start winding each from the surface.

As described above, in the first to third embodiments, the case where the wire 4 is fed on one surface of the bobbin 1 is shown for one wire. In the fourth to sixth embodiments, one of the bobbins 1 is shown. It showed about the case where the feed of the wire 4 in a surface is for 2 wires.

  Next, a multilayer coil in the case where the wire 4 is fed on one surface of the bobbin 1 other than one and two will be described.

(Embodiment 7)
A multilayer coil 700 according to the seventh embodiment of the present invention will be described with reference to FIG. 10A and 10B are diagrams showing a winding method at the winding core end portion of the multilayer coil 700. FIGS. 10A and 10E are front views, FIGS. 10B and 10F are plan views, and FIGS. ) Is a rear view, and (d) and (h) are bottom views. In addition, back view (c), (g) shows the state seen through the bobbin 1 from the front for convenience of explanation. Further, only the wire related to the description is shown, and the other wires are not shown.

  The multilayer coil 700 is formed by winding a wire rod 4A, 4B having substantially the same wire diameter in parallel on a winding core 2 having a quadrangular cross section in parallel. The wire feed surfaces are two surfaces, a front surface 2a and a back surface 2c, which are two opposite surfaces, and the wire feed is 1.5 wires on the front surface 2a and 0.5 wires on the back surface 2c. . The other two planes 2b and bottom 2d are not fed. In this way, when the multi-layer coil 700 is fed with two wires while the wires 4A and 4B go around the winding core 2 and the wires 4A and 4B are wound around the winding core 2 in multiple layers, On the front surface 2a and the back surface 2c, the winding directions of the lower layer and the upper layer are reversed. Thereby, the crossing part 5 where the lower layer and the upper layer wire intersect each other is formed on the front surface 2a and the back surface 2c of the multilayer coil 700. In addition, as shown in FIG. 10E, the multilayer coil 700 has a twisted portion 6 at the end portion of the front surface 2a where the two wire rods 4A and 4B are twisted and the arrangement of the wire rods is switched.

Next, a winding method of the multilayer coil 700 will be described.
(1) Two wires 4A and 4B are started to be wound in parallel from the same surface of the core 2 having a quadrangular cross section.
(2) As shown in FIGS. 10A to 10D, the front 2a feeds 1.5 wires, the back 2c feeds 0.5 wires, the plane 2b and the bottom 2d. Then do not send. In this way, a total of two wires are fed while the wires 4A and 4B go around the winding core 2.
(3) At the front 2a end, as shown in FIG. 10E, the wires 4A and 4B are twisted and wound, and the arrangement of the wires 4A and 4B is switched. Specifically, the wire rod 4A on the inner side of the winding core rides on a gap corresponding to 0.5 wires between the lower wire rod and the flange 3, and is wound on the upper layer. Further, the wire 4B outside the winding core is wound in a direction opposite to the winding of the lower layer, and forms a twisted portion 6 by crossing the wire 4A, and also crosses the lower wire and crosses the lower layer. It winds on the groove | channel between the adjacent wound wires, and is wound by the upper layer. Thus, the twisted part 6 produced by twisting the wire 4A, 4B and the intersecting part 5 produced by intersecting the wire 4B and the lower wire exist at the end of the front surface 2a. In both the twisted portion 6 and the intersecting portion 5, the overlapping of the wire is double, and the twisted portion 6 and the intersecting portion 5 are not wound in a triple manner.
(4) On the next plane 2b, as shown in FIG. 10 (f), the wires 4A and 4B are wound around the end of the core 2 without feeding.
(5) On the next back surface 2c, as shown in FIG. 10 (g), the wires 4A and 4B are wound by feeding 0.5 wires in the direction opposite to the feeding direction of the lower wires. . Thus, in the back surface 2c, the lower layer and the upper layer of the wire intersect each other. However, the intersecting portions 5 are both double and are not rolled up in triplicate.
(6) On the next bottom surface 2d, as shown in FIG. 10 (h), the wire rods 4A and 4B are guided and wound in the groove between the adjacent lower windings without being fed.

  In the multilayer coil 700 according to the seventh embodiment described above, the wire feed surfaces are the front surface 2a and the back surface 2c, and the wire feed is 1.5 for the front surface 2a and 0.5 for the back surface 2c. However, the present invention is not limited to this, and the wire rod feeding surface can be set to an arbitrary surface of the core 2, and the wire rod is fed in total while the wire rod goes around the core 2. If the feed for two wires is applied, the feed of the wire on the wire feed surface can be arbitrarily set. For example, it is possible to perform winding by feeding 0.5 wires on all surfaces (four surfaces) of the core 2. In this case, a twisted portion in which two wire rods are twisted to change the arrangement of the wire rods is formed at one end of each surface of the core 2, and the wire rod bulges in the outer diameter direction on the wire rod feeding surface. Is prevented.

  Moreover, in the multilayer coil 700, although the case where the number of the wire was two was shown, this invention is not limited to this, It is also possible to use three or more. Therefore, consider the case where the number of wires is n (n is an integer of 2 or more), and the n wires are aligned and wound around a core having an N-shaped cross section (N ≧ n). In this case, while the wire rod goes around the winding core, winding is performed by feeding a total of n wires on any surface of the N surfaces of the winding core. Then, at the end of at least one of the surfaces to which the feed is applied, two wires among the n wires are twisted and the arrangement of the twisted wires is changed. By winding n wires in this way, the wire feed surface is prevented from bulging of the wire in the outer diameter direction, and the resulting multilayer coil is compact.

  As can be seen from the seventh embodiment, in the case where n wires (n is an integer of 2 or more) are aligned and wound around a winding core having a polygonal cross section, the total amount of wire rods goes around the winding core. If winding is performed by feeding n wires, the wire feed on the wire feed surface is not limited to an integer number of wires.

  Next, a winding device for a multilayer coil will be described.

(Embodiment 8)
With reference to FIG. 11, a winding apparatus 800 according to the eighth embodiment of the present invention will be described. FIG. 11 is a perspective view showing the winding device 800.

  The winding device 800 winds the wire 4 around the bobbin 12 that rotates together with the spindle shaft 11 that rotates about the axis. The winding device 800 includes a plurality of nozzles 14 for guiding the wire 4 from a wire source (not shown) to the bobbin 12, wire rod feeding means 15 for moving the nozzle 14 in the axial direction of the core 12 a of the bobbin 12, and the arrangement of the nozzles 14. Wire rod twisting means 16 for twisting the replacement wire rod 4 is provided.

The spindle shaft 11 is supported by a spindle support base 20 erected on a base 21 and is rotationally controlled by a spindle motor 22 connected to one end of the spindle shaft 11.

The bobbin 12 is supported by a winding jig 17 fixed to the other end of the spindle shaft 11. The bobbin 12 includes a winding core 12a around which the wire 4 is wound, and flanges 12b provided coaxially with the winding core 12a on both sides of the winding core 12a. A notch 12c for guiding the wire 4 is provided at the beginning of winding. The bobbin 12 is fixed so that the axial direction of the winding core 12 a coincides with the axial direction of the spindle shaft 11.

  The nozzles 14 have a cylindrical shape, are arranged at least as many as the number of wires in a direction substantially orthogonal to the spindle shaft 11, and are supported by the nozzle support portion 18.

  The nozzle support portion 18 penetrates and fixes the plurality of nozzles 14 and supports them integrally, and is accommodated in the housing 26 so as to be rotatable about the axis. The nozzle support portion 18 has a cylindrical shape and has teeth on the outer periphery.

  The wire rod feeding means 15 is screwed into the ball screw 29, a wire rod feed motor 28 disposed on the base plate 27, a ball screw 29 connected to the output shaft of the wire rod feed motor 28 and extending in the axial direction of the spindle shaft 11. An axial movement table 30 that moves in the axial direction of the spindle shaft 11, a linear guide 31 that is arranged on the base plate 27 and extends in the axial direction of the spindle shaft 11, and supports the housing 26 and is fixed to the axial movement table 30. And a support plate 32 that moves along the linear guide 31. Thereby, the nozzle support part 18 accommodated in the housing 26 can be moved in the axial direction of the core 12 a by the action of the wire feeding means 15.

  The wire twisting means 16 includes a nozzle arrangement changing motor 33 connected to the support plate 32, and a rotating member connected to the output shaft of the nozzle arrangement changing motor 33, and the teeth formed on the outer periphery mesh with the teeth on the outer periphery of the nozzle support portion 18. 34. Thus, the nozzle support part 18 and the rotation member 34 constitute a gear, and function as nozzle support part rotation means. Accordingly, the rotation member 34 is rotated by the operation of the nozzle arrangement replacement motor 33, and the rotation is transmitted to the nozzle support portion 18 so that the nozzle support portion 18 is rotated. Thereby, the nozzle 14 revolves around the rotation axis of the nozzle support part 18, and the wire rods 4a and 4b fed out from the nozzles 14a and 14b are twisted and intersect.

  In addition, the winding device 800 includes an axis orthogonal direction moving unit 35 that moves the wire rod feeding unit 15 in the direction orthogonal to the spindle axis (the vertical direction in FIG. 11). The axis orthogonal direction moving means 35 is provided on the base 21 and extends in the direction orthogonal to the spindle shaft 11, a vertical movement motor 37 disposed on the support base 36, and an output shaft of the vertical movement motor 37. A ball screw 38 that is connected and extends in the orthogonal direction of the spindle shaft 11, a linear guide 39 that is fixed to the support base 36 and extends in the orthogonal direction of the spindle shaft 11, and an axis that engages with the ball screw 38 and moves along the linear guide 39. And an orthogonal direction moving table 40. The axis orthogonal direction moving table 40 is fixed to the base plate 27 of the wire rod feeding means 15. Therefore, the base plate 27 moves in the direction orthogonal to the spindle shaft 11 together with the axis orthogonal direction moving table 40. The weights of the axis orthogonal direction moving table 40 and the base plate 27 are supported by a spring 41 attached to the support table 36.

Next, the operation of the winding apparatus 800 will be described. The number of windings will be described by taking the case of two wires as shown in the figure as an example.
(1) The bobbin 12 is fixed to the winding jig 17 so that the axial directions of both the bobbin 12 and the spindle shaft 11 coincide.
(2) The two nozzles 14 a and 14 b are fixed to the nozzle support 18 in an annular shape around the rotation axis of the nozzle support 18.
(3) The wire rods 4a and 4b from the wire rod source (not shown) are fed out from the tips of the nozzles 14a and 14b, respectively, and are held by the clamp 42a of the clamp device 42.
(4) After the wire 4 is wound around the locking pin 43 on the winding jig 17, the wire between the clamp 42 and the locking pin 43 is cut by the cutter 44.
(5) The nozzles 14a and 14b are moved in the axial direction and the orthogonal direction of the spindle shaft 11 by the action of the wire feeding means 15 and the axis orthogonal direction moving means 35, and the wires 4a and 4b are notched provided in the bobbin 12. It guides to the winding core 12a through 12c.
(6) The bobbin 12 is rotated by rotating the spindle shaft 11, and the wires 4a and 4b are wound around the winding core 12a.
(7) The wire rod is fed by operating the wire rod feed motor 28 of the wire rod feed means 15 on a predetermined surface during one rotation of the bobbin 12 and moving the nozzle support portion 18 in the axial direction of the spindle shaft 11. Do. In the case of the multilayer coil according to the first to third embodiments, the wire rods 4a and 4b are fed by one wire in the axial direction of the spindle shaft 11, and the multilayer coil according to the fourth to sixth embodiments. In this case, the wires 4a and 4b are fed by two wires in the axial direction of the spindle shaft 11.
(8) At the end of the core 12a, the nozzle arrangement replacement motor 33 of the wire twisting means 16 is operated to rotate the nozzle support 18 through 180 degrees via the rotating member 34, thereby arranging the two nozzles 14a and 14b. Replace. In this way, the arrangement of the wires is changed by twisting and intersecting the two wires 4a and 4b.
(9) When the winding to the bobbin 12 is finished, the nozzles 14a, 14b are moved in the axial direction and the orthogonal direction of the spindle shaft 11 by the action of the wire feeding means 15 and the axis orthogonal direction moving means 35, and the wire 4a, 4b passes through a notch 12c provided in the bobbin 12. After that, the clamp 42a is moved toward the nozzles 14a and 14b by the clamp device 42, and the wire rods 4a and 4b fed from the tips of the nozzles 14a and 14b are held by the clamp 42a, and between the bobbin 12 and the clamp 42a. The wire 4 is cut by the cutter 44.

  According to the winding apparatus 800 described above, since the wire twisting means 16 is provided, it is possible to change the twist arrangement of the two wires at the end of the core 12a. Therefore, the multilayer coil manufactured by the winding device 800 is prevented from bulging of the wire in the outer diameter direction on the wire feed surface, and becomes a compact multilayer coil.

(Embodiment 9)
With reference to FIG. 12, a winding apparatus 900 according to the ninth embodiment of the present invention will be described. FIG. 12 is a perspective view showing the winding device 900. The same components as those of the winding device 800 described above are denoted by the same reference numerals. The number of windings will be described by taking the case of four lines (4a to 4d) as an example as shown in the figure.

  The winding device 900 differs from the winding device 800 in that the nozzle support portion 18 supports the plurality of nozzles 14 independently, and the wire twisting means 16 independently supports the nozzle support portion 18 of the winding core 12a. It is a point to move in the axial direction. Hereinafter, the winding device 900 will be described focusing on differences from the winding device 800.

  The nozzle support portions 18a to 18d are plate-like members and support the plurality of nozzles 14a to 14d independently.

  The wire rod feeding means 15 is disposed on the base plate 27, a wire rod feed motor 28 disposed on the base plate 27, a ball screw 29 connected to the output shaft of the wire rod feed motor 28 and extending in the axial direction of the spindle shaft 11, and the base plate 27. A linear guide 31 extending in the axial direction of the spindle shaft 11 and an axial moving table 30 that is screwed into the ball screw 29 and moves along the linear guide 31 are provided.

The wire twisting means 16 includes a nozzle arrangement replacement motor 50 disposed on the axial movement table 30, a ball screw 51 connected to the output shaft of the nozzle arrangement replacement motor 50 and extending in the axial direction of the spindle shaft 11, and the ball screw 51. And a second guide 52 that is fixed to the nozzle support portion 18 and a linear guide 53 that is disposed on the guide 30 and extends in the axial direction of the spindle shaft 11. A set (4 sets in the winding apparatus 800) is provided. Thereby, the wire twisting means 16 can move the nozzle support portions 18a to 18d independently in the axial direction of the core 12a.

Next, the operation of the winding apparatus 900 will be described.
(1) The bobbin 12 is fixed to the winding jig 17 so that the axial directions of both the bobbin 12 and the spindle shaft 11 coincide.
(2) The four nozzles 14a to 14d are penetrated and fixed to the nozzle support portions 18a to 18d, respectively. Further, each nozzle arrangement replacement motor 50 corresponding to the nozzles 14a to 14d is operated so that the interval in the axial direction of the core 12a of the nozzles 14a to 14d is equal to one wire (state shown in FIG. 12).
The following steps (3) to (6) are the same as in the winding device 800.
(7) The wire rod is fed by operating the wire rod feed motor 28 of the wire rod feed means 15 on a predetermined surface during one rotation of the bobbin 12 and moving the axial movement table 30 in the axial direction of the core 12a. Do by.
(8) At the end portion of the winding core 12a, the nozzle arrangement replacement motor 50 corresponding to the nozzle support portion 18 that supports the two wire rods to be twisted among the nozzle support portions 18a to 18d is operated, and the two wire rods are moved. The relative position in the axial direction of the core 12a of the nozzle support portion 18 to be supported is changed. In this way, the arrangement of the wires is changed by twisting and intersecting the two wires.
The step (9) is the same as that of the winding device 800.

  As described above, the winding device 900 can move the nozzle support portions 18a to 18d independently in the axial direction of the winding core 12a, and is therefore effective when the number of wires to be wound simultaneously is large.

  The present invention is not limited to the above-described embodiment, and it is obvious that various modifications can be made within the scope of the technical idea.

  The multilayer coil according to the present invention can be applied to a stator coil or the like of a DC motor.

It is a figure which shows the multilayer coil 100 in Embodiment 1 of this invention. 3 is a diagram showing a winding method at a winding core end portion of the multilayer coil 100. FIG. 1 is a front view showing a multilayer coil 100. FIG. It is a figure which shows the winding method in the core end part of the multilayer coil 200 in Embodiment 2 of this invention. It is a figure which shows the winding method in the core end part of the multilayer coil 300 in Embodiment 3 of this invention. It is a front view which shows the multilayer coil 400 in Embodiment 4 of this invention. 4 is a diagram illustrating a winding method at a winding core end portion of a multilayer coil 400. FIG. It is a figure which shows the winding method in the core end part of the multilayer coil 500 in Embodiment 5 of this invention. It is a figure which shows the winding method in the core end part of the multilayer coil 600 in Embodiment 6 of this invention. It is a figure which shows the winding method in the core end part of the multilayer coil 700 in Embodiment 7 of this invention. It is a perspective view which shows the winding apparatus 800 in Embodiment 8 of this invention. It is a perspective view which shows the winding apparatus 900 in Embodiment 9 of this invention. It is a figure which shows the conventional multilayer coil. It is a figure which shows the conventional multilayer coil.

Explanation of symbols

100, 200, 300, 400, 500, 600, 700 Multi-layer coil 800, 900 Winding device 1, 12 Bobbin 2, 12a Core 2a Core front 2b Core flat 2c Core back 2d Core bottom 3, 12b Portions 4, 4A, 4B, 4C, 4D, 4a, 4b, 4c, 4d Wire 5 Crossing portion 6 Twist portion 7 Protrusion 8, 12c Notch 11 Spindle shaft 14, 14a, 14b, 14c, 14d Nozzle 15 Wire rod feeding means 16 Wire rod twisting means 17 Winding jigs 18, 18a, 18b, 18c, 18d Nozzle support portion 26 Housing 27 Base plate 28 Wire rod feed motors 29, 38, 51 Ball screw 32 Support plate 33 Nozzle replacement motor 34 Rotating member 35 Axis orthogonal direction transportation

Claims (5)

A winding method of a multi-layer coil, in which n wires (n is an integer of 2 or more) are wound around a winding core having a polygonal cross section,
Winding the n-wires around the core simultaneously,
While the wire rod goes around the winding core, it feeds n wire rods,
A winding method for a multi-layer coil, wherein at least one of the surfaces to which the feed is applied is replaced by twisting wire arrangement of two wires out of n wires. The multi-layer coil winding method according to claim 1 , wherein a feed for a small number of wires is applied to at least one of the surfaces to which the feed is applied. A winding method of a multi-layer coil, in which n wires (n is an integer of 2 or more) are wound around a winding core having a polygonal cross section,
  Winding the n-wires around the core simultaneously,
  At the n number of surfaces of the winding core, feed one wire.
  Two wires, a wire rod that runs from the lower layer to the upper layer and a wire rod whose winding direction is opposite to that of the lower layer wire, are twisted wires of n-1 of the n surfaces. A winding method of a multilayer coil, wherein the arrangement is changed. A winding method of a multilayer coil in which 2n main wires (n is an integer of 1 or more) are wound around a winding core having a polygonal cross section,
  Winding the 2n main wire around the core simultaneously,
  On the n surfaces of the winding core, feed two wires.
  A winding method for a multi-layer coil, wherein the arrangement of twisted wires is replaced by two wires that run from the lower layer to the upper layer on the n surfaces. 5. The multilayer coil winding method according to claim 4, wherein when n is an integer of 2 or more, n sets of two wires are respectively wound from different surfaces of the core.

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