JP2018026446A - Coil bobbin and transformer including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coil bobbin capable of discriminating the type of coil at a glance even if the shapes are unified, and to provide a transformer capable of reducing the product cost.SOLUTION: A coil bobbin 10 includes protrusions 21, 22 protruding to the outside in the winding radial direction, and capable of indicating the pull-out position of the starting end 32 of a round wire 31, on one end side in the winding radial direction. Since four states can be configured when pulling out the starting end 32 of a round wire 31 for the protrusions 21, 22, respectively, from one side and the other side, difference in the size of the round wire 31 can be distinguished by these states. Consequently, the type of coil can be discriminated at a glance even if the shapes are unified. In a Scott transformer including the coil bobbin 10, separate process of pasting a label for discriminating the type of coil can be eliminated by sharing the coil bobbin 10. Consequently, product cost can be reduced.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a coil bobbin around which a coil wire can be wound, and a transformer including the same.

  The coil bobbin is a frame for maintaining a wound coil wire in a certain shape. For example, the coil bobbin is assembled to a core (iron core) after the coil wire is wound to form a coil. Many transformers and reactors used in power supply circuits use such coil bobbins as represented by Patent Documents 1 and 2 below.

  When a plurality of coil bobbins are assembled to one core, or when one coil bobbin is used for a plurality of types of transformers and reactors, the types of coil bobbins increase. The increase in the types of coil bobbins is likely to be disadvantageous in terms of manufacturing costs and management costs. For this reason, sharing of coil bobbins may be considered.

JP2013-062399A JP 2008-041879 A

  A typical example of common use of parts such as a coil bobbin is unification of the shape. However, in the case of a coil bobbin, the following problems may occur if the shapes are uniformly aligned. For example, when the coil wire wound around the common coil bobbin is wound in the same way and only the wire diameter is different, it may be difficult to determine the difference between the wound coils from the appearance. For example, in a case where the difference in the thickness (wire diameter) of the coil wire material is almost indistinguishable with the naked eye, a mistake in the coil may occur in the process of assembling the coil wound around the coil bobbin to the core.

  Such a mistake in the coil can be suppressed to some extent by, for example, attaching a label that can be discriminated at a glance to the coil bobbin or marking it with paint or the like. However, this requires a separate process for performing such work in a post-process after winding the coil, which may cause a new problem of increasing the number of manufacturing steps for the transformer and the reactor.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a coil bobbin that can be discriminated at a glance even if the shape is unified. Moreover, it aims at providing the transformer which can reduce product cost.

  In order to achieve the above object, a coil bobbin according to claim 1 of the present invention is a coil bobbin capable of winding a coil wire, and protrudes outward in the winding radial direction so as to wind the coil wire. A technical feature is that a convex portion that can indicate a drawing position of the winding start end portion is provided on one end side in the winding axis direction.

  A convex portion that protrudes outward in the winding radial direction and can indicate the drawing position of the winding start end portion of the coil wire is provided on one end side in the winding axis direction. Thereby, since the winding start end part of the coil wire wound around the coil bobbin can be configured with respect to the convex part in two cases of pulling out from one side and pulling out from the other side, for example, the wire of the coil wire rod The difference in diameter can be distinguished by these two modes. Further, when a plurality of convex portions are provided, it is possible to distinguish the difference in the wire diameters of the coil wire rods by the number of modes corresponding to twice the number of convex portions.

  Moreover, the coil bobbin according to claim 2 of the present invention is the coil bobbin according to claim 1, wherein the coil bobbin according to the present invention has corners on an outer peripheral portion around which the coil wire can be wound. In the case where the coil wire is wound toward the corner in the circumferential direction of the outer peripheral portion from the winding start end portion to the corner portion side. Is characterized in that a part of the coil wire from the convex part to the corner part is located in a range where it can contact the outer peripheral part. The “corner portion” includes a so-called “round corner” in which a corner having no clear vertex is rounded.

  In the case where the winding start end is adjacent to the corner of the convex portion and the coil wire is wound from the winding start end toward the corner in the circumferential direction of the outer peripheral portion, the convex portion is a coil Of the wire, the portion from the convex portion to the corner portion is located in a range where it can contact the outer peripheral portion. Thereby, even when pulling out the winding start end portion of the coil wire from the side close to the corner with respect to the convex portion, the coil wire can contact the outer peripheral portion between the convex portion and the corner. For this reason, it is possible to suppress coil winding that may occur when the coil wire to be wound is separated from the outer peripheral portion (floating).

  Furthermore, the coil bobbin according to the third aspect of the present invention is the coil bobbin according to the first or second aspect, wherein a prismatic core can be inserted inward in the winding axis direction. It has a square tube part that can wind the coil wire outward, and when the convex part is located on one end side of the square tube part, the convex part is also located on the opposite side across the core. Technical features.

  When a prismatic core can be inserted inside in the winding axis direction and a coiled tube can be wound outside, and a convex part is located on one end side of the rectangular tube, facing the core A convex portion is also located on the side. Thereby, also on the other end side of the rectangular tube portion, the winding start end portion of the coil wire can be configured with respect to the convex portion so that two modes of pulling from one side and pulling from the other side can be configured. Together with one end side of the tube portion, four modes can be configured. Therefore, for example, it becomes possible to distinguish the difference of the wire diameter of a coil wire material by these four aspects. Further, when a plurality of convex portions are provided, it is possible to distinguish the difference in the wire diameters of the coil wire rods by the number of modes corresponding to twice the number of convex portions.

  A coil bobbin according to a fourth aspect of the present invention is the coil bobbin according to the third aspect, wherein the coil bobbin of the third aspect projects to the other end side in the winding axis direction to the outside in the winding radial direction. It is a technical feature that another convex portion that can indicate a drawing position of the winding start end portion of the coil wire is provided.

  On the other end side in the winding axis direction, another convex portion that protrudes outward in the winding radial direction and can indicate the drawing position of the winding start end portion of the coil wire is provided. Thereby, also on the other end side in the winding axis direction, two modes of pulling the winding start end portion of the coil wire from one side and pulling from the other side can be configured with respect to another convex portion. . Therefore, it becomes possible to distinguish the difference in the wire diameters of the coil wire rods in 4 modes or 8 modes together with the one end side in the winding axis direction. Further, when a plurality of convex portions are provided, it is possible to distinguish the difference in the wire diameters of the coil wire rods by the number of modes corresponding to twice the number of convex portions.

  The coil bobbin according to claim 5 of the present invention is the coil bobbin according to claim 4, wherein one end side in the winding axis direction and the other end side in the winding axis direction are It is provided with a flange part that extends outward in the winding radial direction, and has a first mark on the hook part on the one end side and a second mark on the hook part on the other end side. To do.

  The collar on one end side in the winding axis direction has a first mark, and the collar on the other end side in the winding axis direction has a second mark. Thereby, for example, when the winding start end portion of the coil wire is drawn from one end side in the winding axis direction having the first mark, the difference in the winding method and material of the coil wire has the second mark. It is possible to distinguish from the case where the winding start end portion of the coil wire is drawn from the other end side in the winding axis direction. You may distinguish the difference in the wire diameter of a coil wire by a 1st mark or a 2nd mark.

  Further, the coil bobbin according to claim 6 of the present invention is the coil bobbin according to claim 5, wherein the surface of the flange portion located in the vicinity of the four corners of the end of the rectangular tube portion is It has a technical feature of having four different types of characters, figures or symbols.

  On the surface of the collar part located in the vicinity of the four corners of the end of the rectangular tube part, there are four different types of characters, figures or symbols. Thereby, for example, the difference in the wire diameter of the coil wire can be determined from the characters, figures, or symbols on the surface of the flange close to the drawing position of the winding start end of the coil wire. Differences in the winding method and material of the coil wire may be distinguished by these four types of characters, figures or symbols.

  Moreover, the coil bobbin according to claim 7 of the present invention is the coil bobbin according to claim 1 or 2, wherein the coil bobbin according to claim 1 or 2 is disposed on the other end side in the winding axis direction and on the outer side in the winding radial direction. It is technically characterized by including another convex portion that protrudes and can indicate a drawing position of the winding start end portion of the coil wire.

  On the other end side in the winding axis direction, another convex portion that protrudes outward in the winding radial direction and can indicate the drawing position of the winding start end portion of the coil wire is provided. Thereby, also on the other end side in the winding axis direction, two modes of pulling the winding start end portion of the coil wire from one side and pulling from the other side can be configured with respect to another convex portion. . Therefore, it becomes possible to distinguish the difference in the wire diameters of the coil wire rods in 4 modes or 8 modes together with the one end side in the winding axis direction. Further, when a plurality of convex portions are provided, it is possible to distinguish the difference in the wire diameters of the coil wire rods by the number of modes corresponding to twice the number of convex portions.

  In order to achieve the above object, a transformer of the present invention described in claim 8 of the claims includes a coil bobbin according to any one of claims 1 to 7 and a primary wound around the coil bobbin. Technical features include a coil, a secondary coil wound around the coil bobbin so as to be magnetically coupled to the primary coil, and a core inserted through the coil bobbin.

  By providing the coil bobbin according to any one of claims 1 to 7, it becomes possible to share the coil bobbin, for example, without labeling the coil bobbin or marking with a paint, The type of coil can be identified at a glance. As a result, the coil bobbin can be shared in the subsequent process after winding the coil, without requiring a separate process for performing such operations as sticking of the label, thereby suppressing an increase in the number of manufacturing steps of the transformer. It becomes possible to do.

  In the coil bobbin of the present invention, since the winding start end portion of the coil wire wound around the coil bobbin can be configured with respect to the convex portion in two cases of pulling out from one side and pulling out from the other side, for example, the coil The difference in the wire diameter of the wire can be distinguished by these two modes. Further, when a plurality of convex portions are provided, it is possible to distinguish the difference in the wire diameters of the coil wire rods by the number of modes corresponding to twice the number of convex portions. Therefore, even if the shapes are unified, the type of coil can be determined at a glance.

  Further, in the transformer of the present invention, since it is possible to share the coil bobbin without requiring a separate process for performing such operations as labeling in a subsequent process after winding the coil, it is possible to manufacture the transformer. An increase in man-hours can be suppressed. Therefore, the product cost of the transformer can be reduced.

It is a perspective view which shows the structural example of the coil bobbin which concerns on one Embodiment of this invention, FIG. 1 (A) is what was seen from the one end side, and FIG. 1 (B) was seen from the other end side. 2A is a plan view of the coil bobbin of the present embodiment as viewed from one end side, FIG. 2B is a bottom view of the coil bobbin of the present embodiment as viewed from the other end side, and FIG. 2C is the present embodiment. It is sectional drawing at the time of cut | disconnecting the coil bobbin of this to the radial direction of a square cylinder part. 3A and 3B are partially enlarged views of the coil bobbin of this embodiment, and FIG. 3C is a partial cross-sectional view of the coil bobbin of this embodiment. 4A is an explanatory diagram when the coil wire is wound around the coil bobbin of the present embodiment, and FIG. 4B is an explanatory diagram when the coil wire is wound around the coil bobbin of the comparative example. It is explanatory drawing which shows the example of drawer | drawing-out of a start end part, when a coil wire is wound around the coil bobbin of this embodiment. It is explanatory drawing which shows the example of the drawer | drawing-out aspects AF of the start end part at the time of applying the coil bobbin of this embodiment to the coil bobbin for M seat coils of a Scott transformer. It is explanatory drawing which shows the example of the drawer | drawing-out aspects GL of the start end part at the time of applying the coil bobbin of this embodiment to the coil bobbin for T seat coils of a Scott transformer. It is a perspective view showing an example of composition of a Scott transformer (Scott transformer concerning one embodiment of the present invention) provided with a coil bobbin of this embodiment. It is a circuit diagram which shows the example of a connection of the Scott transformer of this embodiment.

  Hereinafter, embodiments of a coil bobbin of the present invention and a transformer including the coil bobbin will be described with reference to the drawings. First, the structure of the coil bobbin 10 which concerns on this embodiment is demonstrated based on FIGS. FIG. 1 is a perspective view showing a configuration example of the coil bobbin 10. FIG. 1A shows the coil bobbin 10 viewed from one end side, and FIG. 1B shows the coil bobbin 10 viewed from the other end side. It is a thing. 2 (A) is a plan view of the coil bobbin 10 viewed from one end side, FIG. 2 (B) is a bottom view of the coil bobbin 10 viewed from the other end side, and FIG. 2 (C) is a coil bobbin. Cross-sectional views when 10 is cut in the radial direction of the rectangular tube portion are shown.

  3A is a partially enlarged view of one end side of the coil bobbin 10, FIG. 3B is a partially enlarged view of the other end side of the coil bobbin 10, and FIG. Partial sectional views are shown respectively. 4A is an explanatory diagram when the coil wire is wound around the coil bobbin 10, and FIG. 4B is an explanatory diagram when the coil wire is wound around the coil bobbin of the comparative example. It is shown in the figure. FIG. 5 is an explanatory diagram illustrating an example of drawing out the start end when a coil wire is wound around the coil bobbin 10.

  As shown in FIGS. 1 and 2, the coil bobbin 10 is a cylindrical body for maintaining the wound coil wire material in a certain shape. In this embodiment, it is mainly comprised by the flange parts 11 and 12, the square cylinder part 13, etc., These are integrally shape | molded, for example with the nonflammable resin. The rectangular tube portion 13 is a hollow rectangular column having round corner portions 13a, 13b, 13c, and 13d (hereinafter also referred to as “corner portions 13a to 13d”) with rounded corners. For example, as will be described later, a round wire 31 as a coil wire is wound around the outer peripheral portion 15 of the rectangular tube portion 13 to form a primary coil. Therefore, the flange portion 11 is formed on one end side (one end side in the winding axis direction) of the shaft around which the round wire 31 is wound, and the flange portion 12 is formed on the other end side (the other end side in the winding axis direction). Thus, the winding layer of the round wire 31 wound in a plurality of layers is less likely to collapse in the winding axis direction.

  In the present embodiment, the flange portion 11 is not formed over the entire circumference like a sword's heel, but is connected to two opposing long sides of the rectangular tube portion 13. It is comprised by the flanges 11a and 11b. That is, the short side of the rectangular tube part 13 where the flanges 11a and 11b are not formed is formed with a notch part 11c in which a part of the collar is notched, and convex parts 21, 22, 23, which will be described in detail later. 24 (sometimes referred to as “convex portions 21 to 24”) are formed. In addition, the flanges 11a and 11b may be formed on a pair of opposing short sides of the rectangular tube portion 13, and the notches 11c and the convex portions 21, 22, 23, and 24 may be formed on the remaining long sides facing each other. .

  The corner portions 13a to 13d of the rectangular tube portion 13 are formed into rounded round corners because the round wire 31 that can be pressed against the corner portions 13a to 13d at the time of winding is scratched. This is to make it difficult. In addition, a plurality of slightly wider linear grooves 16 are formed in the inner peripheral portion 14 of the rectangular tube portion 13 along the longitudinal direction (axial direction). When the leg portion of the prismatic core is inserted into the hollow portion 20 of the coil bobbin 10 and the coil bobbin 10 is assembled to the core, these linear grooves 16 are connected to the inner peripheral portion 14 and the leg portion of the square tube portion 13. Is provided to form a gap that can be filled with varnish.

  The flange portion 12 is configured in substantially the same manner as the flange portion 11. That is, the flange portion 12 is composed of two flanges 12 a and 12 b connected to a pair of opposing long sides of the rectangular tube portion 13. Further, on the short side of the rectangular tube portion 13 where the flanges 12a and 12b are not formed, a notch portion 12c is formed by notching a part of the collar, and convex portions 25, 26, 27, which will be described in detail later. 28 (sometimes referred to as “convex portions 25 to 28”). In addition, the flanges 12a and 12b may be formed on a pair of opposing short sides of the rectangular tube portion 13, and the notches 12c and the convex portions 25 to 28 may be formed on the remaining long sides facing each other.

  In the present embodiment, alphabetic marks 17 and 18 are displayed on the flange portions 11 and 12. For example, an “M” mark 17 is provided on the surface of the flange portion 11 (the surface not facing the flange portion 12), and “T” is indicated on the surface of the flange portion 12 (the surface not facing the flange portion 11). The marks 18 are formed so as to appear in a convex shape. The “M” mark 17 displayed on the flange portion 11 indicates an M seat coil, and the “T” mark 18 displayed on the flange portion 12 indicates a T seat coil. The M seat coil and the T seat coil will be described later.

  In this embodiment, four types of characters 19 are also displayed on the surfaces of the flange portions 11 and 12. For example, on the surface of the flange portions 11 and 12 (flanges 11a, 11b, 12a and 12b) located near (near) the four corners of the end portion of the square tube portion 13, four types of characters (numerals) “1”, “ “2”, “3” and “4” are formed so as to appear in a convex shape. For example, “1” and “4” are displayed on one flange 11a, 12a, and “2” and “3” are displayed on the other flange 11b, 12b, respectively. In addition to numbers, alphabets (a, b, c, d, etc.) and Greek letters (α, β, γ, δ, etc.) may be used. Instead of the four kinds of characters 19 including such numbers, figures (for example, ○, ◎, Δ, □) and symbols (@, &, ¥, $) are displayed on the flange portions 11 and 12. May be.

  As described above, in the present embodiment, the coil bobbin 10 is formed by the mold so that the characters and the like displayed on the flange portions 11 and 12 appear in a convex shape. However, if the coil bobbin 10 can be formed when the coil bobbin 10 can be formed. The coil bobbin 10 may be formed by a mold so that these characters and the like appear in a concave shape. The marks 17 and 18 may correspond to “first mark” or “second mark” recited in the claims. The character 19 can correspond to a “character, graphic or symbol” recited in the claims.

  As shown in FIG. 3A, convex portions 21 to 24 are formed on the short side of the rectangular tube portion 13 where the flanges 11a and 11b are not formed by the notch portion 11c. Similarly, as shown in FIG. 3B, convex portions 25 to 28 are formed on the short side of the rectangular tube portion 13 where the flanges 12a and 12b are not formed by the notch portion 12c. That is, on one short side, the convex portion 21 and the convex portion 25 are located near “1” of the character 19 described above, and the convex portion 22 and the convex portion 26 are located near “2” of the character 19. positioned. On the other short side, the convex portion 23 and the convex portion 27 are located near “3” of the character 19, and the convex portion 24 and the convex portion 28 are located near “4” of the character 19. ing.

  These convex portions 21 to 24 are formed in a quadrangular prism shape or a truncated pyramid shape. In the present embodiment, the width s in the winding axis direction of the convex portions 21 to 24 is set to be substantially equal to the thickness t of the flange portion 11 (flange 11a, 11b). Similarly, the width s in the winding axis direction of the convex portions 25 to 28 is also set to be substantially equal to the thickness t of the flange portion 12 (flange 12a, 12b) [Condition 1]. Thereby, since the convex parts 21-28 do not protrude toward the square tube part 13 side in the winding axis direction from the flange parts 11 and 12, the round line 31 is formed when the round wire 31 is wound in the circumferential direction of the square tube part 13. It is difficult to contact the convex portions 21 to 28 (the convex portions 21 to 28 are unlikely to obstruct the winding).

  Further, as shown in FIG. 3C, the heights h of the convex portions 21 to 24 are set to be substantially the same [Condition 2]. Thereby, compared with the case where the height of the convex parts 21-24 differs, the flow of resin at the time of shaping | molding becomes favorable, and it is hard to generate | occur | produce a molding defect. As will be described below, the convex portions 21 to 24 are positioned so that the starting end portion 32 of the round line 31 is adjacent thereto, and clearly indicate the drawing position of the starting end portion 32. For this reason, mechanical strength is required so that the start end portion 32 does not break even if it contacts or abuts [Condition 3], and the size that can be visually recognized by an operator who winds the round wire 31 around the coil bobbin 10. Is required [Condition 4]. Therefore, the convex portions 21 to 24 are set with a width s in the winding axis direction and a width p in the winding warp direction so as to satisfy these conditions 3 and 4.

  In FIG. 3 (C), the convex portions 25 to 28 are not shown, but the convex portions 25 to 28 are also formed in the shape of a quadrangular prism or a quadrangular pyramid, and have a height h. Is set almost the same. Thereby, the flow of the resin during molding is improved. Further, the width s in the winding axis direction and the width p in the winding warp direction of the convex portions 25 to 28 can be ensured to have a predetermined mechanical strength and can be visually recognized by the operator, similarly to the convex portions 21 to 24. The size is set. In the present embodiment, the shape of the convex portions 21 to 28 is set to a quadrangular prism or a quadrangular pyramid. However, if each of the above conditions 1 to 4 is satisfied, the shape of the convex portions 21 to 28 is changed to a cylinder or a truncated cone. Alternatively, it may be formed on an elliptic cylinder, an elliptic frustum, or the like.

  In this embodiment, the convex portions 21 to 28 formed in such a shape are positions separated by a predetermined distance dx from the boundary between the notch portion 11c of the flange 11a (flange 11b) and the outer peripheral portion 15 of the rectangular tube portion 13. Is provided with a convex portion 21 (convex portion 23) at a position separated by a predetermined distance dy from the boundary between the notch portion 11c of the opposite flange 11b (flange 11a) and the outer peripheral portion 15 of the rectangular tube portion 13. Convex part 22 (convex part 24) is provided. The distances dx and dy are not equal.

  That is, as shown in FIG. 3A, the predetermined distance dx from the boundary between the notch 11c of the flange 11a (flange 11b) and the outer peripheral portion 15 of the rectangular tube portion 13 to the convex portion 21 (convex portion 23) is It is larger than the predetermined distance dy from the opposite boundary to the convex portion 22 (convex portion 24) (dx> dy). Similarly, as shown in FIG. 3 (B), a predetermined distance dx from the boundary between the notch 12c of the flange 12a (flange 12b) and the outer peripheral portion 15 of the rectangular tube portion 13 to the convex portion 25 (convex portion 27) is , Greater than a predetermined distance dy from the opposite boundary to the convex portion 26 (convex portion 28) (dx> dy). The predetermined distance dx is determined by the drawing position of the start end portion 32 (start end portion 32a) of the round wire 31 wound around the rectangular tube portion 13.

  As shown in FIGS. 4 and 5, when the round wire 31 for the primary coil is started to be wound around the outer peripheral portion 15 of the rectangular tube portion 13, the start end portion 32 of the round wire 31 drawn out in the direction of the winding axis J. Depending on the position, it may be difficult for the round wire 31 to contact the outer peripheral portion 15 due to factors such as the hardness of the round wire 31. For example, as shown in FIG. 4B, when a predetermined distance from the boundary between the notch 11c of the flange 11a and the outer peripheral portion 15 to the convex portion 21 is set to dy (<dx) similar to the convex portion 22. (Convex portion 21 ′ shown in the figure), the starting end portion 32 of the round line 31 ′ is closer to the corner portion 13 a of the rectangular tube portion 13 than when the predetermined distance is dx. Therefore, it is necessary to bend the round wire 31 'at a short distance with respect to the corner portion 13a by approximately 90 degrees.

  Since the round wire 31 ′ is bent at approximately 90 degrees in the winding direction of the round wire 31 ′ at the start end portion 32, the round wire 31 ′ is bent at approximately 90 degrees at the portion of the start end portion 32. After that, it is bent almost 90 degrees at the corner 13a at a shorter distance. Since bending around 90 degrees is performed twice at a short distance with respect to the round wire 31 ′, a portion in which the round wire 31 ′ floats without contacting the outer peripheral portion 15 occurs depending on the hardness of the coil wire rod (the same figure). In particular, the round line 31 "is likely to float near the corner 13a. When the round wire 31 ′ is further wound on the floating round wire 31 ″ in this way, so-called thickening, in which the winding length in the vicinity of the corner portion 13 a increases, may occur.

  In order to suppress the occurrence of such thickening, in the present embodiment, as shown in FIG. 4 (A), it protrudes to a position separated by a predetermined distance dx or more from the boundary between the notch portion 11c and the outer peripheral portion 15 of the flange 11a. A portion 21 is provided. That is, in the case where the starting end portion 32 is adjacent to the corner portion 13a side of the protruding portion 21 and the round wire 31 is wound from the starting end portion 32 toward the corner portion 13a side in the circumferential direction of the outer peripheral portion 15, the protruding portion From 21 to the corner portion 13a, the round wire 31 is located in a range w that can contact the outer peripheral portion 15 continuously (or substantially continuously). This range w is appropriately set depending on, for example, the results of experiments and computer simulations based on the hardness (bending hardness), material, wire diameter, and the like of the round wire 31. In FIGS. 4A and 4B, the round line 31 is colored in gray for the sake of convenience.

  For example, when the round wire 31 is a copper wire having a wire diameter r, a position (range) that is 4 to 6 times the wire diameter r from the boundary between the notch portion 11c and the outer peripheral portion 15 of the flange 11a to the convex portion 21 side. The range from the one side of w) to the position (the other side of the range w) separated from the convex portion 22 by the wire diameter r (reference numeral 32 ′) to the convex portion 21 side is set as the range w. That is, the predetermined distance dx from the boundary between the notch portion 11c of the flange 11a and the outer peripheral portion 15 to the convex portion 21 is 4r to 6r. The position apart from the convex portion 22 by the wire diameter r (reference numeral 32 ′) to the convex portion 21 side is set on the other side of the range w because the starting end portion 32 is located between the convex portion 21 and the convex portion 22. This is because it is necessary to ensure a gap that can be positioned.

  On the other hand, the convex portion 22 is provided at a position away from the boundary between the notch portion 11c and the outer peripheral portion 15 of the opposite flange 11b by a predetermined distance dy. The predetermined distance dy is set to, for example, 1 to 2 times the wire diameter r of the round wire 31. It is necessary to secure a gap where the start end portion 32 can be positioned between the corner portion 13b side of the convex portion 22 and the flange 11b, and the corner portion 13b exists on the opposite side of the winding direction of the round wire 31. This is because it is not necessary to be separated from the boundary between the notch portion 11c of the flange 11b and the outer peripheral portion 15 by a predetermined distance dx or more. In addition, since the convex part 22 is located in the direction which leaves | separates with respect to the flange 11a rather than the convex part 21, the convex part 22 is separated from the boundary of the notch part 11c and the outer peripheral part 15 of the flange 11a more than predetermined distance dx. It is clear.

  The convex portions 23 and 24 are set similarly to the convex portions 21 and 22. That is, the predetermined distance dx from the boundary between the notch 11 c and the outer peripheral portion 15 of the flange 11 b to the convex portion 23 is set to 4 to 6 times the wire diameter r of the round wire 31. Further, the predetermined distance dy from the boundary between the notch portion 11 c and the outer peripheral portion 15 of the opposite flange 11 a to the convex portion 24 is set to 1 to 2 times the wire diameter r of the round wire 31.

  Further, the convex portions 25 and 26 are set in the same manner as the convex portions 21 and 22. That is, the predetermined distance dx from the boundary between the notch 12 c and the outer peripheral portion 15 of the flange 12 a to the convex portion 25 is set to 4 to 6 times the wire diameter r of the round wire 31. The predetermined distance dy from the boundary between the notch 12 c and the outer peripheral portion 15 of the flange 12 b on the opposite side to the convex portion 26 is set to 1 to 2 times the wire diameter r of the round wire 31.

  Further, the convex portions 27 and 28 are set in the same manner as the convex portions 21 and 22. That is, the predetermined distance dx from the boundary between the notch 12 c and the outer peripheral portion 15 of the flange 12 b to the convex portion 27 is set to 4 to 6 times the wire diameter r of the round wire 31. The predetermined distance dy from the boundary between the notch 12 c and the outer peripheral portion 15 of the flange 12 a on the opposite side to the convex portion 28 is set to 1 to 2 times the wire diameter r of the round wire 31.

  By configuring the coil bobbin 10 in this way, as shown in FIGS. 5 and 6 (A) to 6 (C), at one end side of the coil bobbin 10 where the flange portion 11 is formed, the corner of the convex portion 21 is formed. The starting end portion 32 a (starting end portion 32) of the round wire 31 is positioned so as to be adjacent to the portion 13 a side, and the round wire 31 is directed to the corner tube portion 13 toward the corner portion 13 a side in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. The starting end portion 32b (starting end portion 32) of the round wire 31 is positioned between the winding A and the protruding portion 21 and the protruding portion 22, and toward the corner portion 13a side in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. A mode B in which the round wire 31 is wound around the rectangular tube portion 13 and an outer peripheral portion of the coil bobbin 10 by positioning the start end portion 32c (start end portion 32) of the round wire 31 so as to be adjacent to the corner portion 13b side of the convex portion 22. In the circumferential direction of 15, the round wire 31 is directed toward the corner portion 13 a toward the corner portion 13 a. And mode C to winding, it is possible to configure the third aspect. 5 and 6 (A) to 6 (C), the first stage of the winding layer of the primary coil formed by winding the round wire 31 around the rectangular tube portion 13 in a multiple manner. Note that only the second stage and the subsequent stages are not shown. In addition, it should be noted that a secondary coil that is formed by winding a rectangular wire multiple times on the rectangular tube portion 13 is not shown.

  Further, as shown in FIGS. 6D to 6F, the start end portion 32d (start end portion 32) of the round wire 31 is positioned so as to be adjacent to the corner portion 13c side of the convex portion 23 so that the coil bobbin 10 is A mode D in which the round wire 31 is wound around the square tube portion 13 toward the corner portion 13c in the circumferential direction of the outer peripheral portion 15, and a start end portion 32e (start end portion) of the round wire 31 between the convex portion 23 and the convex portion 24. 32) is positioned adjacent to the corner portion 13d side of the convex portion 24 and the mode E in which the round wire 31 is wound around the rectangular tube portion 13 toward the corner portion 13c side in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. In this manner, the starting end portion 32d (starting end portion 32) of the round wire 31 is positioned and the round wire 31 is wound around the rectangular tube portion 13 toward the corner portion 13c in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. It is possible to configure the following three modes. 6 (D) to 6 (F) also illustrate only the first stage of the winding layer of the primary coil formed by winding the round wire 31 around the rectangular tube portion 13 in a multiple manner. It should be noted that illustration of the second and subsequent stages is omitted. In addition, it should be noted that a secondary coil that is formed by winding a rectangular wire multiple times on the rectangular tube portion 13 is not shown.

  Further, as shown in FIGS. 7G to 7L, the round wire 31 is adjacent to the corner 13b side of the convex portion 25 on the other end side of the coil bobbin 10 where the flange portion 12 is formed. The starting end portion 32g (starting end portion 32) of the coil bobbin 10 and winding the round wire 31 around the rectangular tube portion 13 toward the corner portion 13b in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10; The starting end portion 32 h (starting end portion 32) of the round wire 31 is positioned between the convex portions 26, and the round wire 31 is wound around the rectangular tube portion 13 toward the corner portion 13 b in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. The starting end 32i (starting end 32) of the round wire 31 is positioned so as to be adjacent to the corner 13a side of the convex portion 26 and to the corner 13b side in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10 It is possible to configure each aspect of the round wire 31 around the rectangular tube portion 13 and the aspect I That.

  Subsequently, the starting end portion 32j (starting end portion 32) of the round wire 31 is positioned so as to be adjacent to the corner portion 13d side of the convex portion 27, and rounded toward the corner portion 13d side in the circumferential direction of the outer peripheral portion 15 of the coil bobbin 10. A mode J in which the wire 31 is wound around the rectangular tube portion 13 and a circumferential direction of the outer peripheral portion 15 of the coil bobbin 10 by positioning the start end portion 32k (start end portion 32) of the round wire 31 between the convex portion 27 and the convex portion 28. In the aspect K in which the round wire 31 is wound around the square tube portion 13 toward the corner portion 13d side, the start end portion 32l (start end portion 32) of the round wire 31 is adjacent to the corner portion 13c side of the convex portion 28. It is possible to configure each of the aspects L and the aspect L in which the round wire 31 is wound around the rectangular tube part 13 toward the corner part 13d in the circumferential direction of the outer peripheral part 15 of the coil bobbin 10. Six configurations are possible. 7 (G) to FIG. 7 (L), only the first stage of the winding layer of the primary coil formed by winding the round wire 31 around the rectangular tube portion 13 in a multiple manner is shown. Note that the second and subsequent stages are not shown. In addition, it should be noted that a secondary coil that is formed by winding a rectangular wire multiple times on the rectangular tube portion 13 is not shown.

  As described above, in the coil bobbin 10 of the present embodiment, a total of 12 modes of the start end portion of 6 modes (modes A to F) on one end side of the coil bobbin 10 and 6 modes (modes G to L) on the other end side of the coil bobbin 10. Thirty-two drawer patterns can be configured.

  In the above-described aspect B, the start end portion 32b is not positioned between the convex portion 21 and the convex portion 22, but the start end portion 32 is positioned adjacent to the corner portion 13b side of the convex portion 21 (mode). B ′), or by positioning the starting end portion 32 so as to be adjacent to the corner 13a side of the convex portion 22 (mode B ″), it is possible to increase the drawing pattern of the starting end portion 32. Similarly, In the aspect E described above, the starting end portion 32e is not positioned between the convex portion 23 and the convex portion 24, but the starting end portion 32 is positioned so as to be adjacent to the corner portion 13d side of the convex portion 23 (mode E). '), The starting end portion 32 is positioned so as to be adjacent to the corner 13c side of the convex portion 24 (mode E "). Further, in the above-described aspect H, the start end portion 32h is not positioned between the convex portion 25 and the convex portion 26, but the start end portion 32 is positioned so as to be adjacent to the corner portion 13a side of the convex portion 25 (mode). H ′), or the start end 32 is positioned so as to be adjacent to the corner 13b side of the convex portion 26 (mode H ″). Further, in mode K, the start end portion is located between the convex portion 27 and the convex portion 28. Instead of positioning 32k, the start end 32 is positioned so as to be adjacent to the corner 13c side of the protrusion 27 (mode K ′), or the start end 32 is adjacent to the corner 13d of the protrusion 28. Or (position K "). Accordingly, it is possible to increase the lead-out pattern of the start end portion 32 in a total of eight modes (modes B ′, B ″, E ′, E ″, H ′, H ″, K ′, K ″). Therefore, when combined with the above-described 12 aspects of aspects A to L, a drawing pattern of the start end portion 32 of the 20 aspects can be configured.

  As described above, in the coil bobbin 10 of the present embodiment, the convex portions 21 to 24 that protrude outward in the winding radial direction and can indicate the drawing position of the start end portion 32 of the round wire 31 are provided on one end side in the winding axis direction, Moreover, the convex parts 25-28 are provided in the other end side of a winding axis direction. Thereby, eight modes of the case where it pulls out from the one side of each convex part and the case where it pulls out from the other side can be constituted to convex parts 21-24 with respect to convex parts 21-24 of round wire 31 wound around coil bobbin 10. . Further, in addition to the two modes in the case where the starting end portion 32 is pulled out from between the adjacent convex portions, the drawing pattern of the starting end portion 32 can constitute a total of ten modes. Moreover, since the convex part 25-28 comprised similarly is provided also in the other end side of a winding axis direction, the start end part 32 of the round wire 31 wound around the coil bobbin 10 is made with respect to the convex parts 25-28. Eight modes of pulling out from one side and pulling out from the other side of each convex portion can be configured. Further, in addition to the two modes in the case where the starting end portion 32 is pulled out from between the adjacent convex portions, the drawing pattern of the starting end portion 32 can constitute a total of ten modes. Therefore, for example, the difference in wire diameter of the round wire 31 can be distinguished by these 20 modes. Therefore, even if the shapes are unified, the type of coil can be determined at a glance.

  Next, an example in which the coil bobbin 10 that can form the lead-out pattern of the start end portion 32 in 20 modes at the maximum is used for the M seat coil and the T seat coil of the Scott transformer 50 will be described with reference to FIGS. 8 and 9. explain. FIG. 8 illustrates a configuration example of the Scott transformer 50 including the coil bobbin 10. FIG. 9 is a circuit diagram showing a connection example of the Scott transformer 50.

  As shown in FIG. 8, the Scott transformer 50 mainly includes a core 51, an M seat coil 52, a T seat coil 53, and the like. The Scott transformer 50 is a transformer in which a plurality of coils 30a, 30b, 40a, and 40b are Scott-connected so that a three-phase alternating current can be converted into two single-phase alternating currents. Therefore, the core 51 includes a M-side primary coil (hereinafter referred to as “M-seat primary coil”) 30a, a M-seat secondary coil (hereinafter referred to as “M-seat secondary coil”) 40a, T A coil on the primary side of the seat (hereinafter referred to as “T seat primary coil”) 30b and a coil on the secondary side of the T seat (hereinafter referred to as “T seat secondary coil”) 40b are wound. The M seat is also called the “main seat”.

  Specifically, for example, as shown in FIG. 9, the M seat primary coil 30a is connected between the U-W phases of the three-phase alternating current, and between the midpoint of the M seat primary coil 30a and the V phase. The T seat primary coil 30b is connected.

  The M seat primary coil 30a is obtained by winding the round wire 31 around the coil bobbin 10 described above. The M seat secondary coil 40a is formed by winding a rectangular wire 41 on the winding layer of the M seat primary coil 30a. It is a turn. These are collectively referred to as an M seat coil 52. In FIG. 8, it should be noted that the boundary between the M seat primary coil 30a and the M seat secondary coil 40a is represented by a two-dot chain line for convenience. In the present embodiment, the M seat coil 52 is wound around the coil bobbin 10 with the flange portion 11 facing upward (in the direction of the Z-axis arrow in the coordinate system shown in FIG. 8), and on the convex portion 21 of the flange portion 11. From the adjacent position, the start end portion 32 of the M seat primary coil 30a is drawn upward. A U-phase terminal 61 is connected to the starting end 32 of the M seat primary coil 30a. A W-phase terminal 63 is connected to the end portion 33 of the M seat primary coil 30a. The M seat coil 52 corresponds to that shown in FIG.

  The T seat primary coil 30b is obtained by winding a round wire 31 around another coil bobbin 10, and the T seat secondary coil 40b is a rectangular wire 41 on the winding layer of the T seat primary coil 30b. Is wound around. These are collectively referred to as a T seat coil 53. In FIG. 8, it should be noted that the boundary between the T seat primary coil 30b and the T seat secondary coil 40b is represented by a two-dot chain line for convenience. In this embodiment, the T seat coil 53 is wound around the coil bobbin 10 with the flange portion 12 facing upward, and from the position adjacent to the convex portion 26 of the flange portion 12, the start end portion of the T seat primary coil 30 b. 32 is drawn upward. A V-phase terminal 62 is connected to the starting end 32 of the T-seat primary coil 30b. The T seat coil 53 corresponds to that shown in FIG.

  In the present embodiment, for example, when the start end portion 32 is drawn from a position corresponding to FIG. 6C or 7I, the M seat primary coil 30a or the T seat primary coil 30b is wound. It is clearly shown that the diameter of the rotating round wire 31 is 2.5 mm. On the other hand, for example, when the start end portion 32 is pulled out from the position corresponding to FIG. 6A or FIG. 7G, the M seat primary coil 30a or the T seat primary coil 30b is wound. It is clearly shown that the diameter of the rotating round wire 31 is 1.5 mm. Further, for example, when the start end portion 32 is drawn from a position corresponding to FIG. 6B or FIG. 7H, the M seat primary coil 30a or the T seat primary coil 30b is wound. It is clearly indicated that the wire diameter of the round wire 31 is 2 mm.

  In the present embodiment, the core 51 is an iron core portion having a Chinese character “day” shape. For example, the core 51 is formed by combining an E-type iron core having three prismatic leg portions 51a, 51b, and 51c and a prismatic I-type iron core that can close the open ends of the leg portions 51a to 51c. Is configured. Therefore, the core 51 is sometimes called an “EI core”. For example, the core 51 is formed by laminating an E-shaped electromagnetic steel plate and an I-shaped electromagnetic steel plate with the E-shape being alternately reversed every several sheets so that the E-shape is reversed. 54 is pressurized in the stacking direction. As the core 51, an EE core that combines two E-type iron cores may be used.

  That is, the core 51 is clamped by a long plate-like fastening bracket 55 whose upper end portion 51d is pressed by screw fastening of a bolt. Further, the lower end portion 51e of the core 51 is sandwiched between L-shaped fixing brackets 56 that are pressed by screw fastening of bolts and nuts. Thereby, a compressive load acts on the core 51 in the stacking direction. In the present embodiment, these fastening fittings 55 and fixing fittings 56 are formed with bolt mounting holes and mounting grooves (not shown) that are used when mounting and fixing to the device on which the Scott transformer 50 is mounted. Yes.

  The core 51 configured as described above has an M seat coil 52 and a T seat coil 53 attached to the outer leg portions 11b and 11c among the three leg portions 51a to 51c. That is, the leg portion 11b located on the outer side is positioned so that the flange portion 11 is located above the cavity portion 20 of the coil bobbin 10 around which the M seat coil 52 is wound (the flange portion 12 is located below (in the coordinate system shown in FIG. 8). (The Z-axis arrow rear end direction)), and the leg portion 11c located on the other outer side is positioned so that the flange portion 12 is located above the hollow portion 20 of the coil bobbin 10 around which the T seat coil 53 is wound ( It is inserted so that the flange portion 11 is on the lower side. In this embodiment, the M seat coil 52 and the T seat coil 53 are covered with insulating paper 58 and 59 coated with insulating varnish or the like.

  As shown in FIG. 9, various circuits according to the application are connected to the output side of the Scott transformer 50, that is, the M seat secondary coil 40a and the T seat secondary coil 40b. The reference numeral 42 shown in the figure indicates the starting end of the M seat secondary coil 40a and the T seat secondary coil 40b, and the reference numeral 43 indicates the terminal end of the M seat secondary coil 40a and the T seat secondary coil 40b. Indicates. These start end portions 42 are also shown in FIG. 8, but the end portion 43 is not shown in FIG. 8 because it is hidden by the M seat secondary coil 40a and the T seat secondary coil 40b.

  As described above, the Scott transformer 50 according to the present embodiment requires a separate process for performing, for example, a labeling process for discriminating types of coils having different wire diameters in a post-process after coil winding. Therefore, it is possible to share the coil bobbin 10, so that it is possible to suppress an increase in manufacturing man-hours. Therefore, the product cost can be reduced.

  In the above-described embodiment, the two convex portions 21 and the like that can indicate the drawing position of the start end portion 32 are formed on the short side of the rectangular tube portion 13 where the flanges 11a and 11b are not formed. If it is a convex part satisfying all of [1] to [Condition 4], three or more may be provided in a range that can be formed on the short side (or long side) of the rectangular tube part 13. The number of convex portions may be one.

  In the above-described embodiment, the coil bobbin is configured in a rectangular tube shape (the rectangular tube portion 13). However, as long as it is a cylindrical body (tubular shape) around which the coil wire can be wound, a cylindrical shape or an elliptical cylindrical shape is used. Or you may comprise in a polygonal cylinder shape. In addition, if it is possible to ensure mechanical strength that does not deform even when a coil wire having a predetermined thickness is wound, it is not necessary to be a cylindrical body, for example, a surface portion of a rectangular cylindrical shape or a polygonal cylindrical shape is removed. It may be a frame (frame shape) consisting of a side portion.

  Furthermore, in the above-described embodiment, the case where the coil wound around the coil bobbin 10 is used for the Scott transformer 50 has been described as an example. However, if the coil component is a winding component wound around the coil bobbin, for example, A transformer used for a phase AC transformer circuit or the like, or a reactor used for a chopper circuit or the like may be used.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications or changes of the specific examples described above. In addition, the technical elements described in the present specification or drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Furthermore, the technique illustrated in this specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of these objects. Note that the description in parentheses in the [Explanation of Symbols] can clearly indicate the correspondence between the terms used in the above-described embodiments and the terms described in the claims.

10 ... Coil bobbin 11 ... Flange part (saddle part, collar part of one end side)
12 ... Flange part (saddle part, collar part on the other end side)
DESCRIPTION OF SYMBOLS 13 ... Square cylinder part 13a, 13b, 13c, 13d ... Corner | angular part 14 ... Inner peripheral part 15 ... Outer peripheral part 16 ... Linear groove 17 ... Mark (1st mark)
18 ... mark (second mark)
19 ... Character (character, figure or symbol)
20 ... hollow part 21, 22, 23, 24, 25, 26, 27, 28 ... convex part (opposite side convex part, another convex part)
30a ... M seat primary coil (primary coil)
30b ... T seat primary coil (primary coil)
31 ... Round wire (coil wire)
32 ... Start end (winding start end)
33 ... Terminal 40a ... M seat secondary coil (secondary coil)
40b ... T seat secondary coil (secondary coil)
41 ... Flat wire 42 ... Start end 43 ... Termination 50 ... Scott transformer (transformer)
51 ... Core 52 ... M seat coil 53 ... T seat coil 58, 59 ... Insulating paper 61, 62, 63 ... Terminal dx, dy ... Predetermined distance J ... Winding shaft

Claims (8)

A coil bobbin on which a coil wire can be wound,
A coil bobbin comprising a convex portion on one end side in a winding axis direction that protrudes outward in the winding radial direction and can indicate a drawing position of a winding start end portion of the coil wire. The coil bobbin according to claim 1, wherein the coil bobbin is provided with a corner portion on an outer peripheral portion around which the coil wire can be wound, the winding start end portion being adjacent to the corner portion side of the convex portion, and the winding start end. In the case of winding the coil wire from the portion toward the corner in the circumferential direction of the outer peripheral portion,
The said convex part is located in the range in which a part can reach the said outer peripheral part from the said convex part to the said corner | angular part among the said coil wire rods. A prismatic core can be inserted inside in the winding axis direction and a rectangular tube portion can be wound around the coil wire,
3. The coil bobbin according to claim 1, wherein when the convex portion is located on one end side of the rectangular tube portion, the convex portion is also located on an opposite side across the core.   The other end side in the winding axis direction is provided with another convex portion that protrudes outward in the winding radial direction and can indicate a drawing position of the winding start end portion of the coil wire rod. The coil bobbin described. The one end side in the winding axis direction and the other end side in the winding axis direction are each provided with a flange that extends outward in the winding radial direction,
5. The coil bobbin according to claim 4, wherein the flange on the one end side has a first mark and the hook on the other end side has a second mark.   6. The coil bobbin according to claim 5, wherein four different types of characters, figures, or symbols are provided on the surface of the collar portion located in the vicinity of the four corners of the end portion of the rectangular tube portion.   The other end side in the winding axis direction is provided with another convex portion that protrudes outward in the winding radial direction and can indicate a drawing position of the winding start end portion of the coil wire. 2. The coil bobbin according to 2. The coil bobbin according to any one of claims 1 to 7,
A primary coil wound around the coil bobbin;
A secondary coil wound around the coil bobbin so as to be magnetically coupled to the primary coil;
A core inserted through the coil bobbin;
A transformer characterized by comprising.