JP6607809B2 - Coil bobbin, coil and transformer provided with the coil - Google Patents

Description

  The present invention relates to a coil bobbin, a coil in which a winding is wound around the coil bobbin, and a transformer including the coil.

  Conventionally, as a coil bobbin used for a coil for a transformer, it is made of a resin frame having a rectangular ring shape, and windings are wound around an outer peripheral side surface (hereinafter referred to as “outer peripheral side surface”) of the frame. 2. Description of the Related Art A coil bobbin in which a concave groove is formed is known.

  For example, in Patent Document 1, as the first coil bobbin for a primary coil (high voltage coil), both inner wall surfaces are inclined so that the bottom surface side is tapered toward the outer peripheral side surface of a frame having a rectangular ring shape. A coil bobbin having a structure in which a concave groove having a cross-sectional shape is provided is described (see the inner frame 38 in FIG. 7 of Patent Document 1).

  Further, a coil bobbin having the same structure as the first coil bobbin and having a size slightly larger than the first coil bobbin is described as the second coil bobbin for the secondary coil (low voltage coil) (Patent Document 1). (See the outer frame 37 in FIG. 7). Then, the first coil bobbin around which the primary winding is wound is fitted into the hole of the second coil bobbin around which the secondary winding is wound, and the secondary coil is arranged concentrically outside the primary coil. The structure for producing the coil portion of the vessel is described.

  Further, FIGS. 1 and 2 of the cited document 1 show a transformer main body that is assembled by winding an iron core around two legs of the coil part (part corresponding to the long side part of the first and second coil bobbins). (See the transformer 30 in FIGS. 1 and 2).

JP-A-8-51034 Special table 2013-51184 gazette

  In the structure in which the first coil bobbin is fitted into the hole of the second coil bobbin, the primary coil wound around the concave groove of the first coil bobbin has only the upper part of the concave groove opened, and the bottom surface and both sides of the concave groove. The wall portion is in contact with the inner wall surface. For this reason, for example, when the transformer main body is housed in a tank containing insulating oil, the heat generated by the primary coil is received by the insulating oil, and the oil cooling type transformer is released from the tank by the cooling device. There is a problem that the area of the primary coil that contacts the coil (hereinafter referred to as “insulating oil contact area”) is small, and the insulating oil cannot sufficiently receive the heat generated by the primary coil.

  Further, since the upper surface of the concave groove of the first coil bobbin is closed by the second coil bobbin, the volume of the space generated above the concave groove around which the primary winding is wound is small, and the sealed state There is also a problem that the insulating oil entering the space is difficult to convect with the outside of the groove. For this reason, in the structure in which the first coil bobbin is fitted into the hole of the second coil bobbin, the heat dissipation efficiency of the primary coil by the insulating oil is lowered.

  For example, in Cited Document 2, in a configuration in which a coil is manufactured by winding a winding around a concave groove of a coil bobbin, a plurality of cooling ducts (steps) are formed in the direction perpendicular to the winding direction of the winding. A technique is disclosed in which the insulating oil can be convected through the ducts with the outside of the coil bobbin (see the cooling duct 106 of FIG. 15 of the cited document 2).

  The technology described in the cited document 2 is a duct in which the upper surface of the concave groove of the coil bobbin is completely open, and the duct passes from the inner wall surface of one side wall of the concave groove to the inner wall surface of the other side wall through the bottom surface. Is formed. That is, when the winding is wound in the concave groove, the technique described in the cited document 2 communicates both ends of the duct with the open space above the concave groove, and the insulating oil passes through the duct to the outside of the coil bobbin. It is designed to be able to flow.

  In order to increase the cooling efficiency of the structure in which the upper surface of the concave groove of the first coil bobbin is closed by the second coil bobbin, it is conceivable to apply the technique described in the cited document 2. However, since the space above the concave groove of the first coil bobbin is not an open space, even if the technique described in the cited document 2 is applied, the insulating oil is not provided between the concave groove and the outside of the first coil bobbin. It is difficult to convect smoothly. Therefore, it is difficult to improve the heat dissipation efficiency of the primary coil by insulating oil only by the technique described in the cited document 2.

  The present invention has been made in view of the above-mentioned problems, and while increasing the contact area between the primary coil and the insulating oil, the convection efficiency inside and outside the bobbin of the insulating oil is increased, and the coil bobbin having high heat dissipation efficiency is provided. It aims at providing the coil which wound the coil | winding, and the transformer provided with the coil.

  A coil bobbin according to the present invention is a coil bobbin in which a concave groove is provided on the entire outer peripheral side surface of an annular frame body, and an annular coil is produced by winding a winding around the concave groove. The coil bobbin is provided with a gap forming portion for providing a gap between the winding and the inner wall surface of the concave groove.

  According to the above configuration, since the gap forming portion for providing a gap between the winding and the inner wall surface of the groove is provided in the groove of the coil bobbin, the coil produced by winding the coil around the coil bobbin. Is stored and used in a tank containing insulating oil, the contact area with the coil of insulating oil that has entered the concave groove is increased, and the heat receiving efficiency from the coil of insulating oil can be improved. Thereby, the cooling efficiency by the insulating oil of the heat generated in the coil can be improved.

  In the above coil bobbin, the gap forming portion supports the winding by a plurality of rib members that project from the inner wall surface of the concave groove and extend in a direction intersecting the winding direction of the winding. A gap may be formed between the winding and the inner wall surface of the groove.

  According to said structure, the coil wound by the some rib member at the groove of the coil bobbin can be made into the state which floated from the inner wall face of the groove. Thereby, when using the coil produced by winding a coil | winding around a coil bobbin in the tank containing insulating oil, it can enlarge the contact area with the coil of insulating oil which penetrate | invaded the ditch | groove.

  In the coil bobbin, the gap forming portion is formed by forming a plurality of grooves extending in a direction intersecting a winding direction of the winding on the inner wall surface of the concave groove. A gap may be formed between the inner wall surface of the groove.

  According to said structure, a space | gap can be provided between the coil wound by the some groove | channel on the concave groove of the coil bobbin, and the inner wall face of a concave groove. Thereby, when using the coil produced by winding a coil | winding around a coil bobbin in the tank containing insulating oil, it can enlarge the contact area with the coil of insulating oil which penetrate | invaded the ditch | groove.

  In the coil bobbin, the frame body has a pair of opposite frame sides, and an iron core is attached to a part of the frame side of the coil, and the gap forming portion Is preferably provided in the frame side portion of the frame.

  According to the above configuration, when a coil produced by winding a coil bobbin around a coil bobbin is stored in a tank containing insulating oil and used, in a groove on a set of frame sides to which the iron core of the coil bobbin is attached, The amount of infiltrating insulating oil is smaller than the other parts, but since the gap forming part is provided in the part of the set of frame sides, the contact area between the winding of the part and the insulating oil is increased. be able to.

  Further, in the above coil bobbin, one or more holes or one or more grooves penetrating through the side walls of the concave groove are respectively formed on both sides sandwiching a pair of frame sides of the frame body. Good.

  According to said structure, an insulating oil can be made to go in and out between a ditch | groove and the exterior of a coil bobbin with the hole or groove | channel drilled in the side wall of a ditch | groove. Thereby, the convection efficiency of insulating oil improves and the cooling efficiency by the insulating oil of the heat | fever which generate | occur | produces with the coil wound by the ditch | groove can be improved.

  The coil bobbin according to the present invention includes an annular frame having a pair of opposite sides facing each other, and a concave groove provided on the entire outer peripheral side surface of the frame, A coil bobbin for producing an annular coil by winding a winding, wherein one or more holes or one or more grooves penetrating the side wall of the concave groove are formed on both sides of the frame body across the frame side. Each is a coil bobbin that is drilled.

  According to the above configuration, when a coil produced by winding a winding around a coil bobbin is stored and used in a tank containing insulating oil, convection of insulating oil occurs from the lower side to the upper side of the coil bobbin. By the convection, the insulating oil can be caused to flow into the concave groove from the hole or groove on the lower frame side of the coil bobbin. And the insulating oil in a ditch | groove can be made to flow out of a coil bobbin from the hole or groove | channel of the part of the frame side below a coil bobbin. That is, the convection of the insulating oil passing through the concave groove can be improved.

  In the above coil bobbin, a part or all of the one or more holes or the one or more grooves may be used as a winding lead portion for pulling out the winding wound around the concave groove from the frame body. Good.

  According to the above configuration, the hole or groove for convection of the insulating oil into and out of the concave groove of the coil bobbin is also used as the winding lead-out portion of the winding wound around the concave groove. The hole or groove and the winding lead-out portion can be designed efficiently.

  The coil according to the present invention is a coil produced by winding a winding around the concave groove of the coil bobbin according to the present invention.

  According to the coil of the present invention, since the gap forming portion for providing a gap between the winding and the inner wall surface of the concave groove is provided in the concave groove of the coil bobbin, the coil is accommodated in a tank containing insulating oil. When used, the contact area with the coil of insulating oil that has entered the groove is increased, and the heat receiving efficiency from the coil of insulating oil can be improved. Thereby, the cooling efficiency by the insulating oil of the heat generated in the coil can be improved.

  In addition, since the insulating oil can be made to enter and exit between the concave groove and the outside of the coil bobbin by the hole or groove drilled in the side wall of the concave groove, the convection efficiency of the insulating oil is improved and this also occurs in the coil. The cooling efficiency by the insulating oil of the heat which carries out can be improved.

  The transformer according to the present invention is an iron core attached to one or both of a coil part in which a second coil is concentrically arranged on the outside of the first coil and a pair of leg parts opposite to each other of the coil part. The first coil is manufactured by winding a winding around the concave groove of the coil bobbin according to the present invention, and the second coil is formed by fitting the coil bobbin. It is a transformer produced by winding a winding around a concave groove of a second coil bobbin that is externally provided.

  According to the transformer of the present invention, the coil is stored in the insulating oil-filled tank because the gap forming portion for providing a gap between the winding and the inner wall surface of the groove is provided in the groove of the coil bobbin. In the case of the transformer, the contact area with the coil of insulating oil that has entered the groove is increased, and the heat receiving efficiency from the coil of insulating oil can be improved. Thereby, the cooling efficiency by the insulating oil of the heat generated in the coil can be improved.

  In addition, since the insulating oil can be made to enter and exit between the concave groove and the outside of the coil bobbin by the hole or groove drilled in the side wall of the concave groove, the convection efficiency of the insulating oil is improved and this also occurs in the coil. The cooling efficiency by the insulating oil of the heat which carries out can be improved.

  According to the coil bobbin and the like according to the present invention, since the gap groove around which the winding is wound is provided with the gap forming portion for providing a gap between the winding and the inner wall surface of the groove, the coil is insulated with the insulating oil. In the case of a transformer housed in an enclosed tank, the contact area with the coil of insulating oil that has entered the groove is increased, and the heat receiving efficiency from the coil of insulating oil can be improved. Thereby, the cooling efficiency by the insulating oil of the heat generated in the coil can be improved.

  In addition, since the insulating oil can be made to enter and exit between the concave groove and the outside of the coil bobbin by the hole or groove drilled in the side wall of the concave groove, the convection efficiency of the insulating oil is improved and this also occurs in the coil. The cooling efficiency by the insulating oil of the heat which carries out can be improved.

The perspective view which shows the structure of the transformer main body of the transformer provided with the coil produced using the coil bobbin which concerns on this invention. Diagram showing the circuit configuration of the transformer A front view of the first coil bobbin for producing the primary coil (high voltage coil) of the transformer The first coil bobbin is seen from the left side The top view of the first coil bobbin The first coil bobbin is viewed from below AA line sectional view of the first coil bobbin in FIG. BB sectional view of the first coil bobbin in FIG. Sectional drawing of the high voltage coil produced by winding the winding around the first coil bobbin The figure for demonstrating the effect | action and effect of the insulation reinforcement part provided in the said 1st coil bobbin. The figure for demonstrating the effect | action and effect of the other insulation reinforcement part provided in the said 1st coil bobbin. A front view of the second coil bobbin for producing the secondary coil (low voltage coil) of the transformer The second coil bobbin is seen from the left side The top view of the second coil bobbin A view of the second coil bobbin seen from below CC sectional view taken on line CC of FIG. 15 of the second coil bobbin. The figure for demonstrating the manufacturing method of the coil part which has arrange | positioned the secondary coil concentrically outside the primary coil of the transformer Sectional view showing the structure of the coil section of the transformer The figure for demonstrating the effect | action and effect of the groove | channel provided in the concave groove of the said 1st coil bobbin. The figure for demonstrating the effect | action and effect of the notch and window which were provided in the both-sides wall of the concave groove of the said 1st coil bobbin

  Hereinafter, embodiments of a coil bobbin and the like according to the present invention will be described with reference to the drawings.

(Embodiment 1)
In the following description, a coil bobbin used for the primary coil and the secondary coil of the transformer will be described. The transformer according to the present embodiment has a structure in which a secondary coil is concentrically arranged outside the primary coil, and a cylindrical iron core is arranged outside the leg portions of both coils. The coil bobbin according to the present invention is particularly used for producing a primary coil of a transformer.

  FIG. 1 is a perspective view showing a configuration of a main part (transformer main body) of a transformer including a coil manufactured using a coil bobbin according to the present invention. FIG. 2 is a diagram showing a circuit configuration of the transformer.

  A transformer main body 1 shown in FIG. 1 includes an annular coil portion 2 in which a second coil 22 is disposed concentrically outside a first coil 21 (not visible in FIG. 1; see FIG. 17), and a coil portion. 2 and a cylindrical iron core 3 attached to each of two long side portions (hereinafter referred to as “leg portions”). The first coil 21 and the second coil 22 are produced using a first coil bobbin 4 (see FIGS. 3 to 8) and a second coil bobbin 5 (see FIGS. 12 to 16), respectively, as will be described later. ing.

  In the transformer main body 1, a high voltage of 6000 [V] or more from the power system is applied to the first coil 21, and a prescribed low voltage (for example, 100 [V] or 200 [] is supplied to the consumer from the second coil 22. V] is an example of a transformer body used for an oil-filled transformer for distribution (oil-cooled transformer).

  The transformer body 1 corresponds to a portion indicated by a dotted line in the circuit configuration of the transformer shown in FIG. The transformer main body 1 is accommodated in a tank (not shown) after the first coil 21 is connected to the tap changer TL attached to the transformer main body 1. The two high-pressure bushings BS1 (+), BS1 (−) and three low-pressure bushings BS2 (+), BS2 (−), BS2 (G) disposed in the tank are connected to a tap switch TL and a transformer. The second coil 22 of the main body 1 is electrically connected, and the tank is filled with insulating oil (not shown) to complete the transformer having the circuit configuration shown in FIG.

The two high-voltage bushings BS1 (+) and BS1 (−) are used to convert the primary voltage v ₁ (high voltage) (for example, 6300 to 6900 [V]) supplied from the high-voltage distribution line into the first coil of the transformer body 1. a bushing for applying 21, three low-pressure bushing BS2 (+), BS2 (- ), BS2 (G) is a secondary voltage ± _{v 2} to a low-voltage distribution line which is output from the transformer main body 1 This is a bushing for output.

Of the three low pressure bushings BS2 (+), BS2 (−) ₂ and BS2 (G), the low pressure bushing BS (G) is a grounded bushing, and the low pressure bushing BS (+) is a low pressure bushing. A low pressure of + v ₂ (for example, +100 [V]) is output to BS (G), and the low pressure bushing BS (−) is −v ₂ (for example, −100 [V] to the low pressure bushing BS (G). ]) Is a bushing for outputting a low pressure.

  In the following description, the first coil 21 will be referred to as a “high voltage coil 21” and the second coil 22 will be referred to as a “low voltage coil 22”. Further, in order to distinguish the first coil bobbin 4 for producing the high voltage coil 21 and the second coil bobbin 5 for producing the low voltage coil 22, the first coil bobbin 4 is referred to as "high voltage coil bobbin 4" and second The coil bobbin 5 will be referred to as a “low pressure coil bobbin 5”.

As shown in FIG. 2, the winding of the high-voltage coil 21 of the transformer body 1 (hereinafter referred to as “primary winding”) includes a main winding 211 that constitutes a main part of the total number of turns n ₁ , and the high-voltage coil 21. having a number of turns adjusting winding 212 constituting the total winding adjuster of turns n ₁ (the part for adjusting the number of turns of the total number of turns n ₁₎ of the.

Since the transformer body 1 is a step-down transformer, the total number of turns n ₂ of the winding of the low-voltage coil 22 (hereinafter referred to as “secondary winding”) is less than the total number of turns n ₁ of the primary winding. . Since the current flowing through the high voltage coil 21 is smaller than the current flowing through the low voltage coil 22, the wire diameter of the primary winding is smaller than the wire diameter of the secondary winding.

  The winding number adjusting winding 212 includes three small windings 212a, 212b, and 212c. The main winding 211 has a divided winding 211a and a divided winding 211b that are divided into two. As will be described later, the space of the concave groove 401 (see FIG. 4) for aligning the primary windings of the high voltage coil bobbin 4 (the main winding 211 and the winding number adjusting winding 212) is in the width direction (of the high voltage coil bobbin 4). It is divided into two in the thickness direction). The three small windings 212a, 212b, and 212c of the winding number adjustment winding 212 are aligned and wound in one space of the concave groove 401 (hereinafter referred to as “first space”). Part of the side connected to the winding number adjusting winding 212 is aligned and wound in the first space of the concave groove 401, and the rest is the other space of the concave groove 401 (hereinafter referred to as "second space"). Are aligned and wound.

  In the present embodiment, the portion wound in the first space and the portion wound in the second space of the concave groove 401 of the main winding 211 are connected in series outside the coil bobbin 4. is there. Therefore, the main winding 211 is divided into two, one divided winding 211a is aligned and wound in the first space of the groove 401, and the other divided winding 211b is aligned and wound in the second space of the groove 213. I am doing so.

  In the circuit configuration of the transformer body 1 shown in FIG. 2, three small windings 212a, 212b, and 212c are connected in series, and the small winding 212c and the main winding 211 of the winding number adjusting winding 212 are connected in series. Thus, the primary winding is configured. The connection points of the small winding 212a and the small winding 212b, the small winding 212b and the small winding 212c, the small winding 212c and the main winding 211, and the open terminals of the small winding 212a serve as taps.

The tap changer TL is provided with four tap terminals P _{1 to} P ₄ and a common terminal P _c connected to any one of the tap terminals by the switching piece TC. The common terminal _Pc of the tap changer TL is connected to the high voltage bushing BS1 (+). Ends of Komaki line 212a is connected to the tap terminal P ₁ and the tap terminal _{P 2} respectively, at both ends of Komaki line 212b is connected to the tap terminal _{P 2} and the tap terminal _{P 3} respectively, opposite ends of Komaki line 212c, respectively It is connected to the tap terminals _{P 3} and the tap terminal _{P 4.} While each end and the other end of the split winding 211b tap terminal _{P 4} and the high-pressure bushing BS1 discrete winding wirings 211a (-) is connected to the other end and one end of the split winding 211b of the split winding 211a coil bobbin 4 Connected to each other outside.

In FIG. 2, connection points T _{1 to} T ₅ and a relay terminal Q ₁ are shown to indicate connection points between the main winding 211 and the winding number adjustment winding 212. Thus, in FIG. 2, to connect the two ends of the small roll lines 212a to each connection point _{T 1} and the connection point _{T 2,} and connecting both ends of the small roll wire 212b to each connection point _{T 2} and the connection point _{T 3,} Komaki connecting the two ends of the line 212c to a connection point _{T 4} respectively connecting point _{T 3.} Also, connect the two ends of the split windings 211a to the connection point _{T 5} respectively connecting points _{T 4,} connect one end of the split winding 211b to the connection point _{T 5,} the other end of the split winding 211b relay terminal Q ₁ is connected.

  Although not shown in FIG. 1, both ends of the divided winding 211a, both ends of the divided winding 211b, and both ends of the small windings 212a, 212b, and 212c are drawn from the coil portion 2 of the transformer body 1. ing. Further, both ends of the winding (secondary winding) of the low voltage coil 22 and the intermediate position c are drawn out from the coil portion 2 of the transformer body 1.

In the transformer, the total number of turns n ₁ of the high-voltage coil 21 can be switched in four stages by switching the tap terminals P _{1 to} P ₄ connected to the common terminal P _c with the tap switch TL. Three Komaki lines 211a, 211b, respectively turns _n a of _211c, n b, and _{n c,} the number of turns of the primary winding 211 and _{n d,} total number of turns _{n 1} of the high pressure coil 21, _{(n a + n b + n c + n} d), (n b + n c + n d), it can be switched to four kinds of _{(n c + n d),} n d.

  In the following description, a case will be described in which the transformer body 1 according to the present embodiment is applied to a 6600 [V] / (210-105 [V] oil-filled transformer for power distribution.

Since the primary voltage input to the high voltage coil of the transformer varies greatly depending on the distance from the distribution substation around the customer where the 6600 [V] / (210-105) [V] transformer is arranged. In general, power is transmitted from the distribution substation at a voltage higher than 6600 [V]. Therefore, the primary voltage v ₁ input to the high voltage coil 21 of the transformer becomes a high voltage of 6600 [V] or more at a location near the distribution substation, and a high voltage of 6600 [V] or less at a location far from the distribution substation. May be.

Transformer body 1 adjusts the total number of turns _{n 1} of the high voltage coil 21 into four stages according to the size of the primary voltage _{v 1,} the secondary voltage _{v 2} of stable from the low pressure coil 22 (210-105) [V] Output is enabled. Specifically, the primary voltage v ₁ is divided into four types of v _A , v _B , v _C , and v _D (v _A > v _B > v _C > v _D ), and four taps are associated with each voltage value. ing.

The transformation ratio of the transformer body 1 is expressed by (v ₁ / v ₂ ) = (n ₁ / n ₂ ). Since v ₂ and n ₂ are fixed, the total number of turns n ₁ of the high voltage coil 21 is proportional to the primary voltage v ₁ . Therefore, the voltage v _A , v _B , v _C , v _D of each tap is applied to the number of turns of the high-voltage coil 21 (n _a + n _b + n _c + n _d ), (n _b + n _c + n _d ), (n _c + n _d ). , N _d correspond to each other.

The tap voltages v _A , v _B , v _C , and v _D are usually determined by standards, customer specifications, and the like. For example, when v _A = 6750 [V], v _B = 6600 [V], v _C = 6450 [V], and v _D = 6300 [V], v _A −v _B = v _B −v _C = _{v C -v} D = 150 because it is _[V], a _{n a = n b = n c} . That is, the number of turns of the three small windings 212a, 212b, and 212c is the same.

  Next, the structure of the high voltage coil 21 and the low voltage coil 22 will be described. First, the structure of the high voltage coil 21 will be described with reference to FIGS.

  3 is a view of the high voltage coil bobbin 4 (coil bobbin according to the present invention) for producing the high voltage coil 21 of the transformer as viewed from the front, FIG. 4 is a view of the high voltage coil bobbin 4 as viewed from the left side, and FIG. FIG. 6 is a view of the high-voltage coil bobbin 4 seen from above, FIG. 6 is a view of the high-voltage coil bobbin 4 seen from below, FIG. 7 is a cross-sectional view taken along line AA in FIG. 4, and FIG. FIG. FIG. 9 is a cross-sectional view of a high voltage coil 21 produced by winding a primary winding around the high voltage coil bobbin 4.

  In the following description, in FIG. 3, the outer peripheral side surface of the annular high-voltage coil bobbin 4 is referred to as “outer peripheral side surface”, and the inner peripheral side surface is referred to as “inner peripheral side surface”. In the following description, the surface is referred to as “front”, and the left surface is referred to as “back”.

  The high voltage coil 21 is formed into a rectangular ring shape (ring shape) using the high voltage coil bobbin 4. As shown in FIGS. 3 and 4, the high-voltage coil bobbin 4 has a ring shape with a short rounded rectangular shape. The high voltage coil bobbin 4 is produced by molding a resin.

  The high-voltage coil bobbin 4 is provided with a concave groove 401 for winding the primary winding (the main winding 211 and the winding number adjusting winding 212) on the outer peripheral side surface. The two side walls 402 and 403 constituting both wall surfaces of the recessed groove 401 have a rounded rectangular ring shape. The outer dimension (L2 (length in the longitudinal direction) × W2 (length in the short direction)) of the side wall 403 on the back side (hereinafter referred to as “second side wall 403”) is the side wall 402 on the front side (hereinafter referred to as length in the short side direction). , “First side wall 402”) is set to a size smaller than the external dimension (L1 (length in the longitudinal direction) × W1 (length in the short direction)). This is because, as shown in FIG. 17, the high voltage coil bobbin 4 is fitted into the hole portion of the low voltage coil bobbin 5 to produce the coil portion 2 in which the low voltage coil 22 is disposed concentrically outside the high voltage coil 21. .

  Therefore, the outer dimension (L2 × W2) on the back side of the high-voltage coil bobbin 4 is the dimension of the hole portion of the low-voltage coil bobbin 5 (L4 (length in the longitudinal direction) × W4 (length in the short direction)) (FIG. 12). The size is set to be slightly smaller than the reference. On the other hand, the outer dimension (L1 × W1) on the front side of the high-voltage coil bobbin 4 is the outer dimension (L3 (length in the longitudinal direction) × W3 (length in the short direction) of the low-voltage coil bobbin 5 having a rounded rectangular ring shape. )) (See FIG. 12).

  The inner peripheral side surface of the two short side portions 4A (see FIG. 3; hereinafter referred to as “first opposite side portion 4A”) in the opposite side relationship of the high voltage coil bobbin 4 is a flat surface (see FIG. 8). The inner peripheral side surface of two long side portions 4B (see FIG. 3; hereinafter referred to as “second opposite side portion 4B”) in the opposite side relationship of the coil bobbin 4 is a curved surface protruding in a semicircular shape inside. (See FIG. 7). Although the inner peripheral side surface of the first opposite side portion 4A of the high-voltage coil bobbin 4 is also a curved surface, a plate-like insulation reinforcing portion 410A is provided at the tip of the curved surface, so that the high-voltage coil bobbin 4 The surface facing the hole is a flat surface. The insulation reinforcing portion 410A will be described later.

  The reason why the cross-sectional shape of the inner peripheral side surface of the second opposite side portion 4B of the high voltage coil bobbin 4 is a semicircular shape is that a cylindrical iron core 3 is formed on the second opposite side portion 4B of the high voltage coil bobbin 4 as shown in FIG. This is because the inner surface of the circular hole of the iron core 3 is in close contact with the second opposite side portion 4B of the high-voltage coil bobbin 4. Accordingly, each long side of the second opposite side portion 4B of the high voltage coil bobbin 4 corresponds to a leg portion (a portion to which the iron core 3 is attached) of the high voltage coil 21. The radius of the curved cross-sectional shape of the portion corresponding to the leg portion of the high voltage coil bobbin 4 is set to be slightly smaller than the radius of the circular hole of the iron core 3.

  In the following description, for convenience of description, each long side portion of the second opposite side portion 4B of the high voltage coil bobbin 4 may be referred to as a “leg portion 4B”. The iron core 3 is attached to the leg portion 4B of the high-voltage coil bobbin 4 by, for example, attaching a belt-shaped electromagnetic steel plate around the leg portion 4B of the high-voltage coil bobbin 4.

  The concave groove 401 of the high voltage coil bobbin 4 includes a first concave groove 401A around which the main winding 211 is wound and a second concave groove 401B around which the winding number adjusting winding 212 is wound. The second concave groove 401B is formed in the center of the bottom surface 404 of the first concave groove 401A in the width direction (thickness direction of the high-voltage coil bobbin 4, lateral direction in FIG. 4).

  At the center of the bottom surface 405 of the second groove 401B, a dividing wall 406 (see FIG. 4) that divides the space of the groove 401 in the width direction is provided. For example, in FIG. 4, the right space (the space on the first side wall 402 side) of the groove 401 divided by the dividing wall 406 corresponds to the “first space”, and the left side space (the second side wall 403). Side space) corresponds to the “second space”.

  The dividing wall 406 is provided perpendicular to the bottom surface 405 of the second concave groove 401B. The dividing wall 406 is a thin plate-like member having a height from the bottom surface 405 to the vicinity of the upper end of the second side wall 403. The dividing wall 406 is provided on the bottom surface 405 of the high-voltage coil bobbin 4 by integral molding of resin.

  The shape of the second groove 401B is a shape (rectangular shape) in which the bottom surface 405 of the second groove 401B and the inner wall surfaces on both sides rise vertically (see FIGS. 4 and 5). This is because the number of turns when the three small windings 212a, 212b, and 212c are aligned and wound in two layers in the first space of the second concave groove 401B is the same.

  On the other hand, the first groove 401A has a shape (in which the inner wall surfaces on both sides rise from the bottom surface 404 of the first groove 401A with a predetermined inclination angle θ (for example, 120 [°]). Isosceles trapezoidal shape) (see FIG. 4).

  Although not shown in FIGS. 4 to 6, at the four corners of the high-voltage coil bobbin 4, a winding position for aligning and winding the small winding 212 a on the bottom surface 405 of the second groove 401 </ b> B is guided. A guide groove is provided, and a guide groove for guiding a winding position for aligning and winding the divided winding 211a is provided on the bottom surface 404 of the first concave groove 401A. The guide groove is a groove having an arc-shaped cross section having a groove width shorter than ½ of the diameter of the primary winding. A predetermined number of guide grooves are formed in the bottom surface 404 and the bottom surface 405 in the width direction.

  Of the grooves 401 formed on the entire outer peripheral side surface of the high-voltage coil bobbin 4, the primary winding is wound around the grooves 401 (see the groove 401 shown in FIG. 4) formed on the second opposite side portion 4B. The second side wall 403 passes from the first side wall 402 through the bottom surface 405 of the second concave groove 401B in a direction intersecting with the direction (vertical direction in FIG. 4) (direction perpendicular to FIG. 4). A plurality of grooves 407A (see FIGS. 4 and 7) are provided. The plurality of grooves 407A correspond to the “gap forming portion” according to the present invention.

  In the example of FIG. 4, six grooves 407 </ b> A are provided in two long side portions of the high-voltage coil bobbin 4 that face each other. By providing the groove 407A in the concave groove 401, as shown in FIG. 7, the resin thickness d1 of the portion where the groove 407A of the high voltage coil bobbin 4 is provided is thinner than the resin thickness d2 of the other portion.

  The plurality of grooves 407A minimizes the contact area where the lowermost winding contacts the bottom surface 405 of the second concave groove 401B when the primary winding is aligned in multiple layers in the concave groove 401. Thus, the contact area with the insulating oil of the high voltage coil 21 produced by aligning the primary windings around the high voltage coil bobbin 4 in multiple layers is made as wide as possible.

  The cooling of the transformer by the oil cooling method is performed by bringing the insulating oil into contact with the high-voltage coil 21 and the low-voltage coil 22 of the transformer main body 1 and transferring the heat generated in these coils 21 and 22 to the insulating oil, and the insulating oil is tanked. It is performed by discharging to the outside air with a cooling device (for example, a large number of fins attached to the side surface of the tank). Accordingly, the plurality of grooves 407A fulfill the function of increasing the heat receiving efficiency of the insulating oil by increasing the contact area of the insulating oil to the high voltage coil 21 as much as possible. The operation and effect of the plurality of grooves 407A will be described later.

  One short side portion of the first side wall 402 of the high-voltage coil bobbin 4 (upper short side portion in FIG. 3) and one short side portion of the second side wall 403 (upper short side portion in FIG. 3). Are each provided with four notches 408 (see FIG. 5). The four notches 408 are provided in the central portion of the short side portion of the high voltage coil bobbin 4. The four notches 408 in the first side wall 402 and the four notches 408 in the second side wall 403 are provided so that the notches 408 face each other.

  Four notches 408 provided in the first side wall 402 are divided windings 211 a of the main winding 211 and windings of the winding adjustment coil 212 that are aligned and wound in the first space of the groove 401. This is for pulling out both ends of the windings 212a, 212b, and 212c. The four notches 408 are slit-like notches extending from the upper end of the first side wall 402 (the outer peripheral end of the high-voltage coil bobbin 4) to the bottom surface 405 of the second concave groove 401B. The first space communicates with the outside of the first side wall 402 by four notches 408.

  In order to distinguish the four cutouts provided in the first side wall 402, the cutouts are labeled "408A", "408B", "408C", "408D", for example, in FIG. 4 notches 408A, 408B, 408C, 408D are arranged in order.

  For example, small windings 212a, 212b, and 212c are arranged in two layers from the bottom surface 405 in this order in the first space of the second concave groove 401B, and divided windings in the first space of the first concave groove 401A. When 211a is wound in multiple layers from the bottom surface 404, both ends of each winding are drawn from the high-voltage coil bobbin 4 as follows, for example.

  That is, both ends of the small winding 212a are drawn out of the high voltage coil bobbin 4 from the cutout 408A, and both ends of the small winding 212b are drawn out of the high voltage coil bobbin 4 from the cutout 408B. The portion is pulled out from the notch 408C to the outside of the high voltage coil bobbin 4. Then, both end portions of the divided winding 211a are drawn out of the high voltage coil bobbin 4 from the notch 408D.

  The four cutouts 408A, 408B, 408C, and 408D communicate the first space with the outside of the first side wall 402, so that only the function of pulling out both ends of the windings aligned and wound in the first space is used. And has a function of allowing the insulating oil to flow between the first space and the outside of the high-voltage coil bobbin 4. That is, the four notches 408A, 408B, 408C, and 408D are formed in the insulating oil groove 401 when the high voltage coil 21 produced by aligning and winding the primary windings in multiple layers on the high voltage coil bobbin 4 is cooled by the insulating oil. The function of improving the cooling efficiency of the transformer by the oil cooling system is improved by improving the convection efficiency to the inside and outside.

  The four cutouts 408 provided in the second side wall 403 are also both end portions of the windings aligned and wound in the second space, like the four cutouts 408 provided in the first side wall 402. And the function of allowing the insulating oil to flow between the second space and the outside of the high voltage coil bobbin 4 (function of improving convection efficiency).

  Note that the function of pulling out both ends of the winding wound in alignment in the second space has a function of one or two cutouts 408 out of the four cutouts 408.

  For example, in FIG. 5, among the four notches 408 provided on the second side wall 403, if the leftmost notch 408 is a notch 408E for drawing out the winding, the winding is aligned in the second space. Both ends of the divided winding 211b are drawn out from the notch 408E to the outside of the high voltage coil bobbin 4. Note that both ends of the divided winding 211b may be drawn out of the high-voltage coil bobbin 4 from the cutout 408E and the other cutout 408, respectively.

  On the other hand, the other short side portion (the lower short side portion in FIG. 3) of the first side wall 402 of the high voltage coil bobbin 4 may be referred to as four windows 409 (through holes 409). ) And four cutouts 408 (see FIG. 6) are provided on the other short side portion of the second side wall 403 (the lower short side portion in FIG. 3).

  The four windows 409 are for allowing the insulating oil to flow between the first space and the outside of the high voltage coil bobbin 4, and the four notches 408 are for the insulating oil to pass through the second space. This is for flowing between the high-voltage coil bobbin 4 and the outside. The four windows 409 on the first side wall 402 and the four notches 408 on the second side wall 403 are provided so that the windows 409 and the notches 408 face each other. Note that the four windows 409 provided in the first side wall 402 may be notched instead of the through holes.

  In the present embodiment, since the two iron cores 3 are attached to the second opposite side portion 4B of the high voltage coil bobbin 4, in order to avoid interference with the iron core 3, notches 408 for increasing the convection efficiency of the insulating oil and A window 409 is provided on the second opposite side portion 4 </ b> B of the high-voltage coil bobbin 4. Function for improving convection efficiency of insulating oil in eight notches 408 provided in one short side portion of the high-voltage coil bobbin 4 and four notches 408 provided in the other short side portion and four windows 409 Will be described later.

  On the outer surface of the first opposite side portion 4A of the first side wall 402, the insulation between the high voltage coil 21 aligned and wound in the groove 401 and the iron core 3 attached to the leg portion of the high voltage coil bobbin 4 is reinforced. An insulation reinforcing portion 410 is provided.

The iron core 3 attached to the leg portion 4B of the high-voltage coil 21 and the high-voltage coil bobbin 4 aligned and wound in the concave groove 401 is configured to be electrically insulated by the interposition of the resin-made high-voltage coil bobbin 4. Usually, since the transformer is used with the iron core 3 set to the ground potential, the insulation design of the high voltage coil bobbin 4 takes into account the super high voltage in which the lightning surge voltage is superimposed on the high voltage v ₁ applied to the high voltage coil 21. it is necessary to design the thickness of the provisions of the breakdown voltage V _T at the legs 4B of the high-pressure coil bobbin 4 so as not to cause dielectric breakdown.

As shown in FIG. 7, the thickness of the groove 401 formed in the leg portion 4 </ b> B of the high-voltage coil bobbin 4 varies depending on the position of the inner wall surface of the groove 401. The voltage also varies from layer to layer. For example, when a lightning surge occurs in the circuit state shown in FIG. 2, the voltage at the end connected to the high voltage bushing BS (+) of the small winding 212a becomes an extremely high voltage. Since the small winding 212a is aligned and wound in two layers on the bottom surface 405 of the second concave groove 401B, as will be described later, the small winding 212a is connected to the high voltage bushing BS (+) of the second concave groove 401B. The voltage at the position where the end of the wire 212a is drawn (winding drawing position) becomes the highest. Thus, the insulation design of the high-pressure coil bobbin 4, should be designed so that the resin thickness corresponding to the linear distance between the iron core 3 in the windings projected position of Komaki line 212a does not cause dielectric breakdown withstand voltage V _T is there. Note that the resin thickness of the high-voltage coil bobbin 4 at the winding lead position corresponds to the distance of the discharge path when discharge occurs in the iron core 3 through the high-voltage coil bobbin 4 at the winding lead position.

If increasing the resin thickness, increase can be obtained sufficient insulation performance for the provision of breakdown voltage V _T, the amount of resin is increased, an increase in the size of the high-pressure coil bobbin 4, with leads to weight reduction, manufacturing cost There is a problem of doing. Thus, the insulation design of the high-pressure coil bobbin 4, it would be desirable to design the minimum resin thickness D _min satisfying breakdown voltage V _T as much as possible the resin thickness.

In the insulation design of the high voltage coil bobbin 4, it is necessary to consider the creepage distance between the high voltage coil 21 and the iron core B as well as the design of the resin thickness of the high voltage coil bobbin 4. The creepage distance is the distance of the discharge path on the bobbin surface when a discharge occurs in the iron core B along the surface of the high voltage coil bobbin 4 from the high voltage coil 21. Even if you set the resin thickness to a minimum resin thickness D _min, when there is sufficient creepage distance can not be taken part in the high-pressure coil bobbin 4, in that part, a possibility that a discharge is generated at a lower voltage than breakdown voltage V _T There is. Insulation reinforcing portion 410 is intended to reinforce the strength of the insulating high-pressure coil bobbin 4 by lengthening the creepage distance of the portion that may be discharged at a voltage lower than the breakdown voltage V _T is generated.

As described above, a plurality of notches 408 and a plurality of windows 409 are provided on the first opposite side portion 4 </ b> A of the high-voltage coil bobbin 4. As shown in FIG. 1, when the transformer main body 1 is assembled, a plurality of notches 408 and windows 409 provided in the high voltage coil bobbin 4 are positioned to face the core end surface 3 </ b> A with respect to the iron core 3. In the portion where the notch 408 and the window 409 of the coil bobbin 4 are formed, there is a possibility that the creepage distance between the high voltage coil 21 and the iron core B cannot be sufficiently obtained.

  Therefore, in the present embodiment, an insulating reinforcing portion 410A made of a rod-shaped convex piece is provided at a portion between the notch 408 and the window 409 and the core end surface 3A of the iron core 3 of the first opposite side portion 4A of the high voltage coil bobbin 4. Provided. As shown in FIG. 8, the insulation reinforcing portion 410 </ b> A is provided by extending a plate-like member by integral molding at the distal end portion of the curved surface on the inner peripheral side surface of each short side portion of the high-voltage coil bobbin 4. Therefore, the first side wall 402 and the second side wall 403 of the high-voltage coil bobbin 4 are each provided with a member made of a square bar-like convex piece as the insulation reinforcing portion 410A.

  Here, the operation and effect of the insulation reinforcing portion 410A will be briefly described.

  FIG. 10 is a cross-sectional view of the high voltage coil 21 cut at the position of the notch 408A. In addition, although the primary winding is arranged in multiple layers in the concave groove 401 of the high voltage coil bobbin 4, FIG. 10 shows a part of the primary winding for convenience of drawing. Further, in FIG. 10, the portion of the iron core end surface 3 </ b> A when the iron core 3 is attached to the two legs of the coil portion 2 is drawn with imaginary lines.

  The end portion of the small winding 212 a connected to the high voltage bushing BS (+) is drawn out of the high voltage coil bobbin 4 from the notch 408 </ b> A of the concave groove 401 of the high voltage coil bobbin 4. For this reason, in the concave groove 401 of the high voltage coil bobbin 4 when the ultra high voltage superimposed with the lightning surge voltage is applied to the high voltage bushing BS (+), the small winding 212a is drawn into the concave groove 401 from the notch 408A. Accordingly, the voltage at the winding start position P where the aligned winding is performed becomes the highest.

Therefore, as described above, to design the resin thickness of the high-pressure coil bobbins 4 in as much as possible minimum resin thickness D _min, the position P of the groove 401 of the high-pressure coil bobbins 4 in the following provisions of withstand voltage V _T It is necessary to design insulation reinforcement so that discharge does not occur in the path from the core surface 3A of the wound core 3 to the bobbin surface.

In the above description, a case has been described in which the tap changer TL connects the common terminal P _c and tap terminal P _1, tap changer TL is a common terminal P _c and tap terminal P ₂ to P ₄ The same applies when connected. If the common terminal _{P c} connecting the tap terminal _P 2 to P _4, the position P is Komaki line 212b that discharge occurs, Komaki line 212c, becomes a winding start position of the divided windings 211a, Since the winding start positions of these windings 212b, 212c, and 211a are the positions where the notches 408B, 408C, and 408D of the concave groove 401 are provided, the positions near the winding start position P of the small winding 212a and Become.

Therefore, if the insulation reinforcement is designed for the creeping distance of the path along the bobbin surface from the winding start position P of the small winding 212a to the core end surface 3A of the winding core 3, the tap terminal connected to the common terminal _Pc is set to P even when switching to ₂ to P ₄ can be obtained the effect.

  In the high voltage coil bobbin 4 according to the present embodiment, as shown in FIG. 10, between the notch 408 of the first opposite side portion 4A and the hole (the tip of the curved inner peripheral side surface inside the first opposite side portion 4A). 410A of insulation reinforcement part which consists of a rod-shaped convex piece of (part) is provided. The path along the bobbin surface from the position P of the recessed groove 401 to the core end surface 3A of the wound core 3 when the insulation reinforcing part 410A is not provided is a path R1 indicated by a virtual line, but the insulation reinforcing part 410A is provided. In this case, a path along the bobbin surface from the position P of the concave groove 401 to the core end surface 3A of the wound core 3 is a path R2 (path indicated by a thick solid line) that bypasses the surface of the convex piece. Therefore, the creepage distance LS of the path R2 from the position P to the core end surface 3A of the wound core 3 when the insulation reinforcing portion 410A is provided can be longer than the creepage distance of the path R1 indicated by the phantom line.

  Thereby, by providing the notch 408 in the first opposite side portion 4A of the high-voltage coil bobbin 4, the creepage distance of the path from the position P to the core end surface 3A of the wound core 3 is shortened, and the insulation strength is reduced. By providing the reinforcing portion 410A, the insulation strength can be reinforced.

  In the present embodiment, the insulating reinforcing portion 410A made of one convex piece is provided between the notch 408 of the first opposite side portion 4A and the hole, but the insulating reinforcing portion 410A has a plurality of convex pieces. You may comprise. In addition, the insulation reinforcing portion 410A may be constituted by a groove instead of the convex piece. And the cross-sectional shape of a convex piece or a groove | channel is not limited to a rectangle, Arbitrary shapes, such as a triangle, an ellipse, and a trapezoid, are employable.

  Furthermore, the insulation reinforcing portion 410A may be constituted by an uneven portion in which a concave portion and a convex portion are repeated. Also in this case, the cross-sectional shape of the concavo-convex portion is not limited to the sine wave shape, and any wave shape such as a triangular shape or a rectangular wave shape can be adopted. Further, the position where the insulation reinforcing portion 410A is provided can be set to an arbitrary position as long as the creepage distance LS is increased.

As shown in FIGS. 7 and 8, the second side wall 403 of the high-voltage coil bobbin 4 is smaller in size than the first side wall 402, and the height h2 from the bottom surface 405 of the side wall on the back side of the concave groove 401 is front. It is lower than the height h1 from the bottom surface 405 of the side wall. For this reason, there is a possibility that the creepage distance between the high voltage coil 21 and the iron core B cannot be sufficiently obtained even at the peripheral portion of the second side wall 403 of the high voltage coil bobbin 4 (the portion constituting the side wall on the back side of the concave groove 401). is there.

  Therefore, in the present embodiment, an insulation reinforcing portion 410B (see FIG. 8) having a rectangular cross section along the outer periphery of the high voltage coil bobbin 4 is formed on the outer surface of the upper portion of the second side wall 403 of the high voltage coil bobbin 4. It is provided to go around.

  Note that, as shown in FIG. 8, a flange 4031 protruding outward is provided at the upper end of the second side wall 403 of the high-voltage coil bobbin 4. The flange 4031 is formed by fitting the high-voltage coil bobbin 4 (high-voltage coil 21) with the primary winding aligned in the hole of the low-voltage coil bobbin 5 (low-voltage coil 22) with the secondary winding aligned. It functions as an engagement member between the high voltage coil bobbin 4 and the low voltage coil bobbin 5 when the coil part 2 having the low voltage coil 22 concentrically arranged on the outside is manufactured.

  The protrusions of the insulation reinforcing portion 410B provided in parallel with the flange portion 4031 have the same shape as that of the flange portion 4031, and also function as an engagement member between the insulated auxiliary high voltage coil bobbin 4 and the low voltage coil bobbin 5.

  Here, the operation and effect of the insulation reinforcing portion 410B will be briefly described.

  FIG. 11 is a cross-sectional view of the leg 4 </ b> B of the high voltage coil 21. The primary winding is wound in multiple layers in the concave groove 401 of the high-voltage coil bobbin 4, but in FIG. 11, a part of the primary winding is drawn for convenience of drawing. Further, in FIG. 11, the iron core 3 </ b> A when the iron core 3 is attached to the leg portion of the coil portion 2 is drawn with imaginary lines.

  In the portion of the leg portion 4B of the high voltage coil bobbin 4, the discharge path from the winding start position P of the small winding 212a on the bottom surface 405 to the iron core B along the bobbin surface is as a path R3 indicated by a thick line in FIG. The discharge path from the winding start position Q of the split winding 211b on the bottom surface 405 to the iron core B along the bobbin surface is a path R4 indicated by a thick line in FIG.

  In the actual use state (energized state), the creepage distances of the discharge paths R3 and R4 starting from the position P or the position Q may be designed. However, in the “non-grounding test” of the lightning impulse test of the transformer, the high voltage side is connected at once, the low voltage side, the iron core, the ground of the metal fitting, etc. are all grounded and a predetermined test voltage is applied. Under the test conditions, the creeping distance of the discharge steep road starting from the position U in FIG. 11 is the shortest. Therefore, in the design of the creepage distance of the high-voltage coil bobbin 4, the creepage distance of the discharge ramp with the position U as the starting point is designed to be greater than the minimum creepage distance required.

  Since the height h2 from the bottom surface 405 of the second side wall 403 of the high voltage coil bobbin 4 is lower than the height h1 from the bottom surface 405 of the first side wall 402, even if the creepage distance of the route R3 is sufficient, The creepage distance may not be sufficient.

  In the high voltage coil bobbin 4 according to the present embodiment, the outer surface of the peripheral portion of the second side wall 403 is fitted to the fitting portion 503A of the low voltage coil bobbin 5, and is disposed outside the high voltage coil bobbin 4 and the high voltage coil bobbin 4. The low voltage coil bobbin 5 is fixed. For this reason, the creeping distance of the path R4 is increased by using a protrusion fitting member to the fitting portion 503A of the second side wall 403.

  As shown in FIG. 11, the path R <b> 4 passes through the surface of the flange 4031 that is a fitting member from the inner wall surface of the second side wall 403 of the recessed groove 401 to the fitting portion 503 </ b> A, and is outside the second side wall 403. After coming out of the wall surface, it reaches the iron core 3 through the outer wall surface, but in this embodiment, a protruding insulation reinforcement portion 410B is added on the path R4 of the outer wall surface of the second side wall 403. With this configuration, the path R4 has a creepage distance LS that is increased by the amount of passage through the surface of the convex insulation reinforcing portion 410B, and the insulation on the second side wall 403 is reinforced.

  As described above, the insulation reinforcing portion 410B can reinforce the fitting and fixing strength between the high-voltage coil bobbin 4 and the low-voltage coil bobbin 5, and the second side wall from which the height h2 from the bottom surface 405 of the concave groove 401 cannot be sufficiently obtained. There is an effect that the insulation at 403 can be reinforced.

  In the present embodiment, only one ridge is provided as the insulation reinforcing portion 410B. However, the insulation reinforcing portion 410B may be composed of a plurality of ridges. Further, the insulation reinforcing portion 410B may be constituted by a concave line instead of the convex line. And the cross-sectional shape of a protrusion or a groove is not limited to a rectangle, Arbitrary shapes can be employ | adopted.

  Furthermore, the insulation reinforcing portion 410B may be configured by a member having an uneven stripe (a member having a corrugated cross-sectional shape) in which convex stripes and concave stripes are repeated. In this case as well, the cross-sectional shape of the concavo-convex portion is not limited to a rectangular wave shape, and an arbitrary wave shape such as a sine wave shape can be adopted.

  Next, the winding method of the primary winding to the concave groove 401 of the high voltage coil bobbin 4 will be briefly described with reference to FIG. FIG. 9 is a sectional view showing a state in which the main winding 211 and the winding number adjustment winding 212 are aligned and wound in the concave groove 401 of the high-voltage coil bobbin 4.

  In the concave groove 401 of the high-voltage coil bobbin 4, first, the small winding 212a of the winding number adjustment winding 212 is wound in the second space of the second concave groove 401B in a two-layer structure. The small winding 212a is, for example, aligned and wound from the second side wall 403 side to the dividing wall 406 in a state where one end (portion serving as a lead wire) is pulled out from the notch 408A to the outside of the high voltage coil bobbin 4. The small winding 212a is folded back by the dividing wall 406, and is wound up to the second side wall 403 using a recess between the windings formed on the upper surface of the first layer of the small winding 212a as a guide. Then, the other end portion (portion serving as a lead wire) of the small winding 212a is pulled out from the notch 408A to the outside of the high voltage coil bobbin 4.

  Next, the small winding 212b of the winding number adjustment winding 212 is wound on the small winding 212a in a two-layer structure. The small winding 212b is wound in an aligned manner from the second side wall 403 side to the dividing wall 406 with one end portion (portion serving as a lead wire) pulled out from the notch 408B to the outside of the high voltage coil bobbin 4. The small winding 212b is folded back by the dividing wall 406, and is wound up to the second side wall 403 using a depression between the windings formed on the upper surface of the first layer of the small winding 212b as a guide. Then, the other end portion (portion serving as a lead wire) of the small winding 212b is drawn out of the high voltage coil bobbin 4 from the notch 408B.

  Next, the small winding 212c of the winding number adjustment winding 212 is wound on the small winding 212b in a two-layer structure. The small winding 212c is wound in an aligned manner from the second side wall 403 side to the dividing wall 406 with one end portion (portion serving as a lead wire) pulled out from the notch 408C to the outside of the high voltage coil bobbin 4. The small winding 212c is folded back by the dividing wall 406, and is wound up to the second side wall 403 using a recess between the windings formed on the upper surface of the first layer of the small winding 212b as a guide. Then, the other end portion (portion serving as the lead wire) of the small winding 212c is drawn out of the high voltage coil bobbin 4 from the notch 408C.

  Next, the split winding 211a of the main winding 211 is wound around the first concave groove 401A in a multilayer structure. Since the small winding 212c is wound on the upper end of the second concave groove 401B, the divided winding 211a is wound on the small winding 212c.

  The divided winding 211a is aligned and wound from the second side wall 403 side to the divided wall 406 in a state where one end (portion serving as a lead wire) is pulled out from the notch 408D to the outside of the high voltage coil bobbin 4. The divided winding 211a is folded back by the dividing wall 406, and is wound up to the second side wall 403 using a depression between the windings formed on the upper surface of the first layer of the divided winding 211a as a guide. Thereafter, the split winding 211a is folded while being folded each time it reaches the inner wall surface of the split wall 406 and the second side wall 403 by using a depression between the windings formed above the split winding 211a of each layer as a guide. It is wound until the number reaches a predetermined number. Then, the other end (portion serving as a lead wire) of the divided winding 211a is drawn out of the high voltage coil bobbin 4 from the notch 408D.

  Next, the divided winding 211b of the main winding 211 is wound in the first space of the concave groove 401 with a multilayer structure. The divided winding 211b is aligned and wound from the first side wall 402 side to the divided wall 406 in a state where one end portion (portion serving as a lead wire) is pulled out from the notch 408E to the outside of the high voltage coil bobbin 4. The divided winding 211b is folded back by the dividing wall 406, and is wound up to the first side wall 402 using a depression between the windings formed on the upper surface of the first layer of the divided winding 211b as a guide. After that, the divided winding 211b is folded while being folded each time it reaches the inner wall surface of the divided wall 406 and the first side wall 402 by using the depression between the windings formed above the divided winding 211b of each layer as a guide. It is wound until the number reaches a predetermined number. Then, the other end (portion to be a lead wire) of the divided winding 211b is pulled out from the notch 408E to the outside of the high voltage coil bobbin 4.

  Next, the structure of the low voltage coil 22 will be described with reference to FIGS.

  12 is a view of the low voltage coil bobbin 5 for producing the low voltage coil 22 of the transformer as viewed from the front, FIG. 13 is a view of the low voltage coil bobbin 5 as viewed from the left side, and FIG. FIG. 15 is a view as seen from above, FIG. 15 is a view when the low-voltage coil bobbin 5 is seen from below, and FIG. 16 is a cross-sectional view taken along line CC in FIG.

  The low voltage coil 22 is formed into a rectangular ring shape (ring shape) using the low voltage coil bobbin 5. As shown in FIGS. 12 and 13, the low voltage coil bobbin 5 has a short rounded rectangular ring shape, and the shape viewed from the side of the low voltage coil bobbin 5 is substantially bilaterally symmetric. The low-voltage coil bobbin 5 is also produced by molding a resin.

  In the following, for convenience of description, in FIG. 13, the surface along the outer periphery of the ring shape is referred to as “outer peripheral side surface”, and the surface along the inner periphery is referred to as “inner peripheral side surface”. The surface is referred to as “front”, and the left surface is referred to as “back”.

  The low voltage coil bobbin 5 has a height dimension (dimension in the width direction in FIG. 13) that is substantially the same as the high voltage coil bobbin 4. The low voltage coil bobbin 5 is formed with a concave groove 501 for winding the secondary winding on the outer peripheral side surface, and the shape of the hole portion of the low voltage coil bobbin 5 is formed into a rounded rectangular shape (see FIG. 12). The reason why the shape of the hole portion of the low-voltage coil bobbin 5 is a rounded rectangular shape is that, as shown in FIG. 17, the high-voltage coil bobbin 4 is fitted and attached to the hole portion.

  The two side walls 502 and 503 constituting both wall surfaces of the concave groove 501 have a rounded rectangular shape when viewed from the front or the back. The dimension (L4 (length in the longitudinal direction) × W4 (length in the short direction)) of the hole portion of the side wall 502 on the front side (hereinafter referred to as “first side wall 502”) is the high voltage coil bobbin 4 The size is slightly larger than the dimension (L2 × W2) on the outer peripheral side of the second side wall 403. The dimension on the outer peripheral side of the side wall 502 (L3 (length in the longitudinal direction) × W3 (short) The length in the hand direction)) is set to be approximately the same as the dimension (L1 × W1) on the outer peripheral side of the first side wall 402 of the low-voltage coil bobbin 5 (see FIG. 3).

  Two long sides in the opposite-side relationship between the inner peripheral side surface of the two short-side portions 5A (see FIG. 12; hereinafter referred to as “first opposite-side portion 5A”) and the high-voltage coil bobbin 4 in the opposite-side relationship of the low-voltage coil bobbin 5 The inner peripheral side surface of the portion 5B (see FIG. 12, hereinafter referred to as “second opposite side portion 5B”) is a flat surface (see FIG. 16). This is because the high voltage coil bobbin 4 is fitted into the hole portion of the low voltage coil bobbin 5.

  In the following description, for convenience of description, the long side portions of the second opposite side portion 5B of the low-voltage coil bobbin 5 may be referred to as “leg portions 5B”.

  A rear side wall 503 (hereinafter referred to as “second side wall 503”) is used to fit the second side wall 403 of the high-voltage coil bobbin 4 when the high-voltage coil bobbin 4 is fitted into the hole portion. A fitting portion 503A (see FIGS. 12 and 16) is formed. The fitting portion 503A is formed in a ring shape along the inner periphery of the hole of the second side wall 503. The fitting portion 503A is formed by extending the wall surface of the second side wall 503 by a predetermined dimension inside the hole.

  On the inner surface of the fitting portion 503A (the surface facing the second side wall 403 of the high voltage coil bobbin 4 when the high voltage coil bobbin 4 is fitted in the hole of the low voltage coil bobbin 5), a narrow groove along the inner periphery of the hole 5031 and 5032 (see FIGS. 12 and 16) are provided. The grooves 5031 and 5032 are provided with a flange 4031 (see FIG. 7) and an insulation reinforcing portion 410B (see FIG. 7) provided on the first side wall 402 of the high voltage coil bobbin 4 when the high voltage coil bobbin 4 is fitted into the hole of the low voltage coil bobbin 5. Reference) is a groove for fitting.

  The fitting portion 503 </ b> A is provided with four notches 504 at two short sides of the second side wall 503. These notches 504 are eight notches 408 formed in two short side portions of the second side wall 403 of the high voltage coil bobbin 4 when the high voltage coil bobbin 4 is fitted into the hole of the low voltage coil bobbin 5. This is to prevent the second side wall 503 from being blocked. That is, the eight notches 504 are for preventing the insulating oil from entering and exiting the concave groove 401 of the high-voltage coil bobbin 4 when the transformer is manufactured.

  The widths of the eight notches 504 are substantially the same as the eight notches 504 provided on the second side wall 503. Further, the four notches 504 in one short side portion (the upper short side portion in FIG. 12) of the second side wall 503 are when the high voltage coil bobbin 4 is fitted into the hole of the low voltage coil bobbin 5. One short side of the second side wall 503 is arranged such that the four notches 408 provided in the upper short side portion of the second side wall 403 of the high voltage coil bobbin 4 overlap with the four notches 504, respectively. It is provided in the side part. Further, the four notches 504 in the other short side portion (the lower short side portion in FIG. 12) of the second side wall 503 are when the high voltage coil bobbin 4 is fitted into the hole of the low voltage coil bobbin 5. In addition, four notches 408 provided on the second side wall 403 of the high-voltage coil bobbin 4 are provided on the other short side portion of the second side wall 503 so as to overlap with the four notches 504, respectively. ing.

  Support portions 505A and 505B (see FIG. 13) are provided in pairs on one short side portion of the first side wall 502 and the second side wall 503 (FIG. 12 shows the upper short side portion). It has been. The two support portions 505A and 505B are plate-like members for attaching the tap changer TL. The support portions 505A and 505B are provided on the first side wall 502 and the second side wall 503 by integral molding of resin. The support portion 505A is formed so that the plate member protrudes outward from the outer periphery of the first side wall 502 (in FIG. 13, the plate member protrudes upward from the upper end of the first side wall 502). Similarly, the support portion 505B is formed so that the plate member protrudes outward from the outer periphery of the second side wall 503 (in FIG. 13, the plate member protrudes upward from the upper end of the second side wall 503). .

  A winding lead-out portion 506 for pulling out the secondary winding is provided at an appropriate position on the portion of the first side wall 502 where the support portion 505A is provided. The winding lead portion 506 is formed by a notch extending from the upper end of the first side wall 502 to the bottom surface 5011 of the groove 501.

  The concave groove 501 has a shape (rectangular cross-sectional shape) in which both inner wall surfaces rise perpendicularly to the bottom surface 5011 of the concave groove 501 (see FIG. 13). At the four corners of the low-voltage coil bobbin 5, as with the high-voltage coil bobbin 4, guide grooves 5012 (see FIGS. 13 to 15) that guide the winding position for winding the secondary winding on the bottom surface 5011 of the concave groove 501. ) Is provided. The guide groove 5012 is a groove whose cross-sectional shape having a groove width shorter than ½ of the diameter of the secondary winding is an arc shape.

  Next, the winding method of the secondary winding to the concave groove 501 of the low voltage coil bobbin 5 will be briefly described.

  The secondary winding is wound around the concave groove 501 with a multilayer structure. The secondary winding is wound in an aligned manner from the first side wall 502 side to the second side wall 503 with one end portion (portion serving as a lead wire) drawn out from the winding lead portion 506 to the outside of the low voltage coil bobbin 5. The The secondary winding is folded at the second side wall 503, and is wound up to the first side wall 502 using a depression between the windings formed on the upper surface of the first layer of the secondary winding as a guide. After that, the secondary winding is folded each time it reaches the inner wall surface of the second side wall 503 and the first side wall 402 with the depression between the windings formed above the windings of each layer as a guide. It is wound until the number reaches a predetermined number. Then, the other end of the secondary winding (portion serving as the lead wire) is drawn out of the low-voltage coil bobbin 5 from the winding lead-out portion 506.

  The high voltage coil 21 produced by aligning the primary winding in the concave groove 401 of the high voltage coil bobbin 4 is compared with the low voltage coil 22 produced by aligning the secondary winding in the concave groove 501 of the low voltage coil bobbin 5. As shown in FIG. 17, the high voltage coil bobbin 4 is fitted into the hole portion of the low voltage coil bobbin 5 from the front side and integrated.

  When the back side of the high-voltage coil bobbin 4 is fitted into the hole portion of the low-voltage coil bobbin 5 from the front side of the low-voltage coil bobbin 5, the peripheral portion of the second side wall 503 of the high-voltage coil bobbin 4 is It contacts the fitting portion 503A. Thereafter, when the high-voltage coil bobbin 4 is further pushed into the low-voltage coil bobbin 5 side, as shown in FIG. 18, the flange portion 4031 formed on the outer surface of the peripheral portion of the second side wall 503 and the insulation reinforcing portion 410B (protruding member) ) Are respectively fitted in the grooves 5031 and 5032 of the fitting portion 503A, and the high-voltage coil bobbin 4 is fixed to the low-voltage coil bobbin 5. Thereby, the coil part 2 by which the low voltage coil 22 is concentrically arranged outside the high voltage coil 21 is produced.

  Next, the operation of the groove 407A provided in the concave groove 401, which is a characteristic configuration of the high voltage coil bobbin 4 according to the present embodiment, and the notch 408 and the window 409 provided in the first and second side walls 402 and 403 are described. The effect will be described.

  First, the operation and effect of the groove 407A provided in the concave groove 401 will be described with reference to FIG.

  FIG. 19 is a cross-sectional view of the high voltage coil 21 produced by winding the primary winding in the concave groove 401 of the high voltage coil bobbin 4. 19A is a cross-sectional view of a portion where the groove 407A of the first opposite side portion 4A of the high voltage coil bobbin 4 is present, and FIG. 19B is a groove 407A of the first opposite side portion 4A of the high voltage coil bobbin 4. It is sectional drawing in the part between them.

  As shown in FIG. 7, since the bottom surface 4071 of the plurality of grooves 407A is lower than the bottom surface 405 of the second concave groove 401B, the high voltage coil 21 in which the primary winding is aligned and wound in multiple layers in the concave groove 401 is a high voltage. In the second opposite side portion 4B of the coil bobbin 4, as shown in FIG. 19B, only the portion 407B between the adjacent grooves 407A (hereinafter, this portion is referred to as “winding support portion 407B”) is used. The portion of the groove 407A does not contact the bobbin.

  Accordingly, the high voltage coil 21 in which the primary windings are wound in multiple layers in the concave groove 401 has a gap 407C in the groove 407A at the second opposite side portion 4B of the high voltage coil bobbin 4 as shown in FIG. Can be lifted from the inner wall surface of the bobbin. For this reason, in the second opposite side portion 4B of the high voltage coil bobbin 4, the contact area where the high voltage coil 21 contacts the inner wall surface of the concave groove 401 is smaller than when the groove 407A is not provided.

  When the transformer body 1 shown in FIG. 1 is stored in a tank filled with insulating oil, the insulating oil enters the concave groove 401 of the high voltage coil bobbin 4 and contacts the high voltage coil 21 in which the primary winding is wound around the concave groove 401. To do. When the high-voltage coil 21 generates heat, the insulating oil receives the heat at a portion in contact with the surface of the high-voltage coil 21. And the cooling efficiency of insulating oil becomes high, so that the heat receiving efficiency is high.

  The heat receiving efficiency of the insulating oil increases as the area (contact area) where the insulating oil is in direct contact with the high-voltage coil 21 increases. When the surface of the high voltage coil 21 is in close contact with the bottom surface 404 and the bottom surface 405 of the concave groove 401 of the high voltage coil bobbin 4 and the inner wall surfaces of the first side wall 402 and the second side wall 403, the insulating oil directly contacts the high voltage coil 21. In addition, it is difficult to move the insulating oil in the contacting portion.

  In the high voltage coil bobbin 4 according to the present embodiment, a plurality of gaps 407C are formed between the high voltage coil 21 and the concave groove 401 in the second opposite side portion 4B. The contact area where the insulating oil directly contacts the high voltage coil 21 increases at the portion. Since each gap 407C communicates with the opening of the groove 401, the insulating oil received from the high voltage coil 21 can easily move toward the opening of the groove 401 in the gap 407C (FIG. 19 (a) oil entry and exit arrows).

  Therefore, the high voltage coil bobbin 4 according to the present embodiment has an effect of improving the heat receiving efficiency of the insulating oil from the high voltage coil 21.

  In the present embodiment, a plurality of grooves 407A (or a plurality of winding support portions 407B) are formed in a direction orthogonal to the winding direction of the primary winding (vertical direction in FIG. 4). The plurality of grooves 407A may be formed in any direction as long as the strip-shaped winding support 407B intersects the winding direction of the primary winding.

  In the present embodiment, six grooves 407A are provided in each long side portion of the high-voltage coil 21, but the number of grooves 407A is not limited to this. In the present embodiment, the shape of the groove 407A is a horizontally long rectangular shape, and the shape of the winding support portion 407B is a strip shape. However, the shape of the groove 407A and the winding support portion 407B is limited to these shapes. Any shape can be adopted as long as the contact area with the groove 401 of the high voltage coil 21 can be reduced.

  Next, operations and effects of the plurality of notches 408 and windows 409 provided in the first and second side walls 402 and 403 will be described with reference to FIG.

  FIG. 20 is a view for explaining the convection of the insulating oil passing through the concave groove 401 of the high-pressure coil bobbin 4 and is a view of the coil portion 2 as viewed from the front.

  Since the transformer body 1 shown in FIG. 1 is housed in the tank in a posture in which two iron cores 3 are horizontally arranged, the posture of the coil part 2 in the tank is as shown in FIG. The low-pressure coil bobbin 5 has a vertically long rectangular shape.

  In a transformer in which the transformer body 1 is housed in a tank containing insulating oil, the insulating oil normally circulates in the direction from the top to the bottom in the periphery of the tank and from the bottom to the top in the center of the tank. So convection. The high voltage coil bobbin 4 according to the present embodiment is provided with a plurality of notches 408 and a plurality of windows 409 in the lower short side portion and the upper short side portion, so that insulation that convects in the tank is provided. As shown in FIG. 20, the oil flows into the first space of the concave groove 401 from the four windows 409 provided in the short side portion on the lower side of the first side wall 402 of the high-pressure coil bobbin 4, The coil bobbin 4 flows into the second space of the concave groove 401 from the four cutouts 408 provided in the lower side portion of the second side wall 403 of the coil bobbin 4 (in FIG. 20, the four cutouts 408 are I can't see it.)

  The insulating oil that has flowed into the first space of the recessed groove 401 passes through the left and right long sides of the high voltage coil bobbin 4 as shown by the bold / dotted arrows in FIG. Rise to part. Then, the rising insulating oil flows out of the high-pressure coil bobbin 4 from the four notches 408 provided in the upper short side portion of the high-voltage coil bobbin 4. Similarly, the insulating oil that has flowed into the second space of the concave groove 401 passes through the left and right long side portions of the high voltage coil bobbin 4 and rises to the short side portion on the upper side of the high voltage coil bobbin 4. It flows out from the four notches 408 provided in the short side portion to the outside of the high voltage coil bobbin 4.

  The insulating oil receives the heat generated by the high voltage coil 21 by contacting the high voltage coil 21 while moving in the concave groove 401 of the high voltage coil bobbin 4. Therefore, the heat generated in the high voltage coil 21 is generated by the convection described above. 4 can be efficiently discharged to the outside.

  Further, at the left and right long sides of the high voltage coil bobbin 4 in the concave groove 401, the contact area between the insulating oil and the high voltage coil 21 is made as much as possible by supporting the high voltage coil 21 with a plurality of winding support portions 407B. Since it is increased, the heat receiving efficiency of the insulating oil is improved. Therefore, in the high voltage coil bobbin 4 according to the present embodiment, the heat generated in the high voltage coil 21 can be efficiently discharged to the outside of the high voltage coil bobbin 4 by the synergistic effect of the improvement of the convection efficiency and the improvement of the heat receiving efficiency. .

  As described above, the eight cutouts 408 provided in one short side portion of the high voltage coil bobbin 4, the four cutouts 408 provided in the other short side portion of the high voltage coil bobbin 4, and the four windows 409 are provided. The number of the cutouts 408 and the windows 409 is not limited to the above-mentioned number because the insulating oil is mainly used to enter and exit between the outside of the high-pressure coil bobbin 4 and the inside of the groove 401. Absent.

  For example, in FIG. 3, the number of notches 408 and windows 409 provided in the lower short side portion of the high voltage coil bobbin 4 may be 3 or less, or 5 or more. Of the four notches 408 provided on the upper short side portion of the high-voltage coil bobbin 4, notches that are not used for the winding lead portion of the primary winding (for example, notches 408 other than the notches 408A to 408E). Also, the number is not limited to the above number, and can be set to an arbitrary number. Further, the shape of the notch 408 is not limited to the slit shape, and any shape can be adopted.

  As described above, according to the high voltage coil bobbin 4 according to the present embodiment, a plurality of notches 408 and windows 409 are provided on the upper and lower short sides of the first side wall 402 and the second side wall 403. In addition, since the plurality of grooves 407A for increasing the contact area between the insulating oil and the high voltage coil 21 are provided in the left and right long side portions of the concave groove 401, the heat receiving efficiency of the insulating hot water from the high voltage coil 21 is The convection efficiency of the insulating oil in the concave groove 401 can be increased. Therefore, the cooling efficiency of the oil-filled transformer can be improved by using the high voltage coil 21 produced by using the high voltage coil bobbin 4 according to the present embodiment for the transformer.

  In the above embodiment, the dividing wall 406 is provided in the concave groove 401 of the high-voltage coil bobbin 4. However, the dividing wall 406 is not necessarily required, and the present invention is also applied to a high-voltage coil bobbin without the dividing wall 406. be able to.

  In the above embodiment, a groove 407A for forming the air gap 407C only in the high-voltage coil bobbin 4, a plurality of notches 407 and a plurality of windows 409 for convection of the insulating oil into and out of the concave groove 401. However, the low-pressure coil bobbin 5 may be provided with grooves or notches that perform the same function.

  In said embodiment, although the coil part 2 used for the transformer main body 1 was demonstrated, this invention is not limited to a transformer, It is widely applied to the static induction apparatus using the coil part which has the same structure. Can be used.

DESCRIPTION OF SYMBOLS 1 Transformer body 2 Coil part 21 1st coil (high voltage coil)
211 Main winding 212 Winding adjustment winding 3 Iron core 4 First coil bobbin (high voltage coil bobbin)
4A 1st opposite side part 4B 2nd opposite side part 401 Concave groove 401A 1st recessed groove 401B 2nd recessed groove 402 1st side wall 403 2nd side wall 4031 ridge part 404 Bottom face of 1st recessed groove 404A Guide Groove 405 bottom surface of second groove 405A guide groove 406 dividing wall 407A groove (gap forming portion)
407B Winding support portion 407C Air gap 4071 Bottom surface of groove 408 Notch 409 Window (hole)
410, 410A, 410B Insulation reinforcement 5 Second coil bobbin (low pressure coil bobbin)
5A First opposite side portion 5B Second opposite side portion 501 Concave groove 5011 Concave groove bottom surface 5012 Guide groove 502 First side wall 503 Second side wall 503A Fitting portion 504 Notch 505A, 505B Support portion 505 Second concave Bottom of groove 506 Winding lead

Claims (6)

A coil bobbin in which a groove is provided on the entire outer peripheral side surface of the annular frame, and a coil is wound around the groove to produce an annular coil.
The bottom surface of the concave groove is provided perpendicular to the bottom surface, and a dividing wall that divides the space of the concave groove in the width direction is provided,
In the concave groove, there is provided a gap forming portion that provides a gap between the winding and the inner wall surface of the concave groove , and between the winding and the wall surface of the divided wall ,
The gap forming portion is formed by supporting the winding with a plurality of rib members protruding in an inner wall surface of the concave groove and extending in a direction intersecting the winding direction of the winding. A gap is formed between the inner wall surface of the groove and
The gap forming portion is a coil bobbin that is a gap extending in a direction intersecting a winding direction of the winding on the wall surface of the dividing wall, and that is continuous with the gap formed by the plurality of rib members. . A coil bobbin in which a groove is provided on the entire outer peripheral side surface of the annular frame, and a coil is wound around the groove to produce an annular coil.
The bottom surface of the concave groove is provided perpendicular to the bottom surface, and a dividing wall that divides the space of the concave groove in the width direction is provided,
In the concave groove, there is provided a gap forming portion that provides a gap between the winding and the inner wall surface of the concave groove, and between the winding and the wall surface of the divided wall,
The gap forming portion is formed between the winding and the inner wall surface of the concave groove by drilling a plurality of grooves extending in a direction intersecting the winding direction of the winding on the inner wall surface of the concave groove. Forming a void in the
The gap forming portion is a coil bobbin that is a gap extending in a direction intersecting with a winding direction of the winding on the wall surface of the dividing wall and is continuous with the gap formed by the plurality of grooves . The frame has a pair of opposite frame sides,
An iron core is attached to a part of the frame side of the frame of the coil,
The gap forming portion is provided at a portion of the frame side of the frame,
The coil bobbin according to claim 1 or 2 . 4. The coil bobbin according to claim 3 , wherein one or more holes or one or more grooves penetrating the side wall of the concave groove are further formed in both side portions sandwiching a pair of frame sides of the frame body. . The coil produced by winding a coil | winding to the concave groove of the coil bobbin as described in any one of Claims 1 thru | or 4 . A coil part in which a second coil is concentrically arranged outside the first coil;
An iron core attached to one or both of a pair of leg portions in the opposite side relationship of the coil portion,
The first coil is manufactured by winding a coil around the concave groove of the coil bobbin according to any one of claims 1 to 4 .
The second coil is manufactured by winding a winding around a concave groove of a second coil bobbin that is externally mounted on the outside of the coil bobbin by fitting the coil bobbin.
Transformer.

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