JP6981498B2 - Antenna device and manufacturing method of antenna device - Google Patents

Description

The present invention relates to an antenna device and a method for manufacturing the antenna device.

In recent years, smart key systems have been put into practical use in vehicles such as automobiles and houses. This smart key system sends and receives information about an ID code, etc. wirelessly as electromagnetic waves, and when the ID code, etc. is collated, the owner does not use a mechanical key, for example, a door in a vehicle or a house. It is possible to lock and unlock, and to start and stop the engine. In such a smart key system, an antenna device including a coil antenna is used for transmitting and receiving information.

As this antenna device, for example, there is a technical content disclosed in Patent Document 1. The antenna device disclosed in Patent Document 1 includes a first magnetic material core, a first coil, a second magnetic material core, and a second coil.

The first magnetic material core has a flat rod shape, a first coil is arranged on the outer peripheral side of the first magnetic material core, and one end of the first coil is a first terminal. It is connected. The second magnetic core has a toroidal closed magnetic circuit structure, and is magnetically saturated when a signal radio wave is transmitted, but is not magnetically saturated when a signal radio wave is received. Further, the second coil is wound around the second magnetic core. One end of the second coil is connected to the other end of the first coil and the other end of the second coil is connected to the second terminal.

Japanese Patent No. 5050223

By the way, in the configuration disclosed in Patent Document 1, a special magnetic core called a second magnetic core is used, and a second coil wound around the second magnetic core is used to obtain a resonance frequency. Is being adjusted. Therefore, it may be structurally complicated.

Further, in the LC resonance circuit, since the resonance frequency is set in a narrow range, the product of LC can be changed only in a narrow range as well. On the other hand, regarding the first coil, there is a tightly wound portion, but in the tightly wound portion, the change in the inductance value L per turn is, for example, about 10 μH. There is something that becomes. In addition, the capacitors used in the resonant circuit generally have variations in manufacturing characteristics (for example, ± 5%). Therefore, it may be necessary to adjust the inductance value L of the first coil every 1 μH as needed, but such adjustment is difficult. Therefore, it becomes difficult to absorb the variation in the capacitance value C and thereby suppress the variation in the product of the inductance value L and the capacitance value C, which is required when obtaining the resonance frequency and the like, within the resonance range.

The present invention has been made in view of this problem, and an object thereof is an antenna device and an antenna capable of easily adjusting an inductance value within a narrow tolerance range while having a simple structure. It is intended to provide a method of manufacturing an apparatus.

In order to solve the above problems, one side surface of the antenna device of the present invention includes a core formed of a magnetic material and a bobbin body arranged on the outer peripheral side of the core and having a partition portion in the middle of the longitudinal direction. A coil formed by winding a wire around the bobbin body is provided, and the coil is configured by winding the winding density of the wire wire from one side of the bobbin body to the partition portion in a dense state. A dense winding portion and a sparse winding portion formed by winding the lead wire from the partition portion to the other side of the bobbin in a sparse winding state are provided in the sparse winding portion. Is provided with a first layer and a second layer, and the winding directions of the first layer and the second layer are different, so that the lead wire constituting the first layer and the second layer are configured. An antenna device is provided characterized in that the wires are overlapped with each other so as to intersect with each other.

Further, on the other side surface of the antenna device of the present invention, in addition to the above-mentioned invention, a terminal mounting portion to which a terminal member is mounted is further provided on one side of the bobbin body, and the dense winding portion is sparse. It is preferable that the terminal mounting portion is provided on the terminal mounting portion side rather than the winding portion.

Further, in the other aspect of the antenna device of the present invention, in addition to the above-mentioned invention, in the sparse winding portion, the lead wire forming the first layer and the lead wire forming the second layer in the side wall portion of the bobbin body are further formed. It is preferable that they are arranged so as to be located in the same layer.

Further, in addition to the above-mentioned invention, the other side surface of the antenna device of the present invention further comprises that the conductors constituting the first layer and the conductors constituting the second layer are in the width direction orthogonal to the longitudinal direction of the bobbin body. On the other hand, it is preferable that they intersect at an angle within the range of 3 degrees to 177 degrees.

Further, in the other aspect of the antenna device of the present invention, in addition to the above-mentioned invention, it is preferable that the length of the loose winding portion is equal to or longer than the length of the tight winding portion.

Further, in the other aspect of the antenna device of the present invention, in addition to the above-mentioned invention, it is preferable that the length of the sparse winding portion is equivalent to the length of the dense winding portion.

Further, in addition to the above-mentioned invention, the other side surface of the antenna device of the present invention further comprises that the distance between the adjacent conductors located on the most opposite side in the longitudinal direction of the bobbin body is the distance between the adjacent conductors located on the most one side. It is preferable that the distance between the matching conductors is different.

Further, in addition to the above-mentioned invention, the other side surface of the antenna device of the present invention further comprises that the distance between the adjacent conductors located on the most opposite side in the longitudinal direction of the bobbin body is the adjacent one located on the most one side. It is preferable that the conductors are provided shorter than the distance between the matching conductors.

Further, one aspect of the manufacturing method of the antenna device of the present invention is a core insertion step of inserting a core formed of a magnetic material into a core insertion portion of a bobbin body having a partition portion in the middle of the longitudinal direction, and a bobbin body. A coil forming step of winding the lead wire to form a coil is provided, and the coil forming step is configured by winding the winding density of the lead wire from one side of the bobbin body to the partition portion in a dense state. A dense winding portion and a sparse winding portion formed by winding the lead wire from the partition portion to the other side of the bobbin in a sparse state are formed. In the sparse winding portion, the first After winding the layer, by winding the second layer whose winding direction is different from that of the first layer, the conductors constituting the first layer and the conductors constituting the second layer intersect with each other. It is characterized by the fact that it is doing.

According to the present invention, it is possible to provide an antenna device capable of easily adjusting an inductance value while having a simple structure.

It is a perspective view which shows the whole structure of the antenna device which concerns on 1st Embodiment of this invention. It is a perspective view which shows the state which removed the coil among the antenna device shown in FIG. It is a side sectional view which shows the structure of the antenna device shown in FIG. It is a perspective view which shows the structure of the bobbin body of the antenna device shown in FIG. It is a top view which shows the part where the coil is wound in the bobbin part of the antenna device shown in FIG. It is an enlarged plan view which shows the winding state of the lower layer conductor and the upper layer conductor wire in the antenna device which concerns on this embodiment. It is a top view which expands and shows the winding state of the lower-layer conductor and the upper-layer conductor in the antenna device as a comparative example. It is a perspective view which shows the structure of the antenna device which concerns on 2nd Embodiment of this invention. It is a perspective view which shows the structure of the bobbin body and the connection terminal of the antenna device shown in FIG. FIG. 3 is a plan view showing the shapes of the three connection terminals included in the antenna device shown in FIG.

(First Embodiment)
Hereinafter, the antenna device 10A according to the first embodiment of the present invention will be described with reference to the drawings.

Further, in the following description, the XYZ Cartesian coordinate system may be used. Among them, the X direction is the longitudinal direction of the antenna device 10A, the X1 side is the side where the connector connection portion 40A described later is located, and the X2 side is the opposite side. Further, the Z direction is the thickness direction of the antenna device 10A, the Z1 side is the upper side in FIG. 2, and the Z2 side is the lower side in FIG. Further, the Y direction is a direction orthogonal to the XZ direction (width direction), the Y1 side is the right front side in FIG. 1, and the Y2 side is the opposite back left side.

<Overall configuration of antenna device 10A>
FIG. 1 is a perspective view showing the overall configuration of the antenna device 10A. FIG. 2 is a perspective view showing a state in which the coil 50A is removed from the antenna device 10A. FIG. 3 is a side sectional view showing the configuration of the antenna device 10A. As shown in FIGS. 1 to 3, the antenna device 10A has a core 20A, a bobbin body 30A, a coil 50A, a connection terminal 60A, and a case 90A as main components.

As shown in FIGS. 2 and 3, the core 20A is formed of a magnetic material and is provided in a long shape (rod shape) long in the X direction. Further, the core 20A has a rectangular cross section when viewed from the front. The core 20A is made of a magnetic material, and the magnetic material includes, for example, various ferrites such as nickel-based ferrite or manganese-based ferrite, various magnetic materials such as permalloy and sendust, and various magnetic materials. It is possible to use a mixture of materials.

Further, as shown in FIG. 2, a bobbin portion 31A of the bobbin body 30A is attached to the outer peripheral side of the core 20A. The material of the bobbin body 30A is preferably a thermoplastic resin or a thermosetting resin having excellent insulating properties. An example of the material constituting the bobbin body 30A is PBT (polybutylene terephthalate), but other resins may be used as the material. Further, it is more preferable to use a heat-resistant resin for the bobbin body 30A in view of the fact that the bobbin body 30A may be damaged by heat due to soldering, welding, or the like.

FIG. 4 is a perspective view showing the configuration of the bobbin body 30A. As shown in FIGS. 1 to 4, the bobbin body 30A is provided with a bobbin portion 31A, a terminal mounting portion 35A, and a connector connecting portion 40A. The bobbin portion 31A is provided with a winding frame portion 32A, a partition portion 33A, and a core insertion portion 34A.

The winding frame portion 32A may have a tubular shape, but in the present embodiment, the winding frame portion 32A is provided in an appropriately punched shape. Specifically, as shown in FIG. 4, the punched portion 32A4 and the slit 32A5 are provided on the top surface 32A2 side (upper side; Z1 side) and the bottom surface 32A3 side (lower side; Z2 side) while leaving the side wall portion 32A1. It is configured to be provided. In particular, the slit 32A5 is provided on the other end side (X2 side) in the longitudinal direction (X direction). Further, the other end side (X2 side) of the slit 32A5 is in an open state. Therefore, when the lead wire 51A is wound around the winding frame portion 32A in a state where a predetermined tension is applied, the core 20A inserted in the core insertion portion 34A is wound and the core 20A is partially held.

Further, the bobbin portion 31A is also provided with a partition portion 33A. The partition portion 33A is a portion for separating the dense winding portion 53A of the coil 50A and the sparse winding portion 54A. In the configuration shown in FIG. 4, the partition portion 33A is, for example, a protruding portion in which the side wall portion 32A1 is projected, but the top surface 32A2 or the bottom surface 32A3 side of the winding frame portion 32A may be projected. ..

Further, the core insertion portion 34A is a hole-shaped portion that penetrates the bobbin portion 31A in the longitudinal direction (X direction), and is a portion into which the core 20A is inserted. A core holding projection 32A6 that abuts on the core 20A is provided on the inner wall side of the side wall portion 32A1 facing the core insertion portion 34A. The number of core holding protrusions 32A6 may be any number, but in the configuration shown in FIG. 4, they are provided on one side (X1 side) of the core insertion portion 34A in the longitudinal direction (X direction). The core 20A is held in the core insertion portion 34A by the core holding projection 32A6 and the inner wall of the bobbin portion 31A by winding the lead wire on the other end side (X2 side).

Further, the terminal mounting portion 35A is a portion to which the connection terminal 60A (see FIGS. 1 and 2) is mounted. The terminal mounting portion 35A is provided with an opening 35A1 penetrating in the vertical direction, and the entwined portion 62A of the pair of connection terminals 60A is exposed in the opening 35A1. The terminal of the lead wire 51A of the coil 50A is entwined with each entwining portion 62A, and after the entanglement, the coil 50A and the connection terminal 60A are electrically connected by soldering or the like.

A partition wall 35A2 is provided on the other end side (X2 side) of the terminal mounting portion 35A in order to separate the terminal mounting portion 35A and the core insertion portion 34A. When the core 20A abuts on the partition wall 35A2, the core 20A is positioned in the core insertion portion 34A.

Here, a substrate on which a capacitor, a resistor, or the like is mounted may be mounted on the terminal mounting portion 35A. When mounting a board, a part of the connection terminal 60A such as the entwined portion 62A penetrates the board and is soldered at the penetrating part, so that the conductor pattern of the board and the connection terminal 60A are electrically connected. It will be in a state of being connected. When the board is attached to the terminal mounting portion 35A, it is preferable that the board is fitted to the terminal mounting portion 35A.

Further, the terminal mounting portion 35A is continuously provided with a connector connecting portion 40A. In the present embodiment, the connector connecting portion 40A is provided along the width direction (Y direction) orthogonal to the longitudinal direction (X direction). The connector connection portion 40A has a bottomed connector hole (not shown), and one end side (Y1 side) of the connector hole is partitioned by a partition wall portion 41A.

Here, as shown in FIG. 4, the partition wall portion 41A is provided with a terminal hole 42A extending in the width direction (Y direction), and the connection terminal 60A is inserted into the terminal hole 42A. .. Therefore, the connection terminal 60A inserted into the terminal hole 42A can protrude into the connector hole. In this embodiment, since a pair of connection terminals 60A is provided, a pair of terminal holes 42A also exists. However, the number of terminal holes 42A can be appropriately changed according to the number of connection terminals 60A.

Further, an external connector inserted into the connector hole is electrically connected to the connection terminal 60A protruding inside the connector hole. As a result, it is possible to conduct a current through the coil 50A and the like, which will be described later.

Next, the coil 50A will be described. FIG. 5 is a plan view showing a portion of the bobbin portion 31A around which the coil 50A is wound. As shown in FIG. 5, the coil 50A is provided with a dense winding portion 53A and a sparse winding portion 54A. The dense winding portion 53A is a portion of the coil 50A that is wound on one side (X1 side; terminal mounting portion 35A side) of the winding frame portion 32A in the longitudinal direction (X direction). On the other hand, the sparse winding portion 54A is a portion wound from the partition portion 33A to the other side (X2 side) of the winding frame portion 32A in the longitudinal direction (X direction) with the partition portion 33A as a boundary. ..

In the configuration shown in FIG. 5, the dense winding portion 53A and the sparse winding portion 54A have a configuration in which the lead wire 51A is wound in two layers, for example, one end side (X direction) of the winding frame portion 32A. The winding is started from the X1 side), reaches the other end side (X2 side) of the winding frame portion 32A, and then reaches one end side (X1 side) while winding again. Therefore, the conductor 51A of the lower layer (first layer) and the conductor 51A of the upper layer (second layer) are in a state of intersecting (crossing). However, the dense winding portion 53A and the sparse winding portion 54A are not limited to winding two layers, and may be wound in any number of layers such as four layers or six layers.

It should be noted that the other end side (X2 side) of the winding frame portion 32A may be configured to have a locking means for shifting and holding the conducting wire 51A. By this locking means, the conductor 51A is locked on the other end side (X2 side) of the winding frame portion 32A, so that the conductor 51A of the lower layer (first layer) and the conductor 51A of the upper layer (second layer) are engaged. , A state of good crossing (crossing) may be realized. Further, the conductor 51A of the lower layer (first layer) and the conductor 51A of the upper layer (second layer) are 3 degrees to the width direction (Y direction) orthogonal to the longitudinal direction (X direction) of the bobbin body 30A. It can be configured to intersect at an angle within the range of 177 degrees. Within this angle range, the conductor 51A of the upper layer (second layer) does not remain in the recess between the conductors 51A of the adjacent lower layer (first layer), and the inductance value is adjusted. It becomes easy to perform.

As is clear from FIG. 5, the sparse winding portion 54A is a portion having a lower winding density than the dense winding portion 53A. That is, the number of times the lead wire 51A is wound per unit length in the sparse winding portion 54A is smaller than that in the dense winding portion 53A. Therefore, in the sparse winding portion 54A, a relatively large gap S1 exists between the adjacent conductors 51A and 51A.

Here, on the wide surface (XY surface) of the winding frame portion 32A, the distance between the adjacent conductors 51A and the conductors 51A is defined as pitches P1, P2 ... Pn. The pitch P1 is the distance between the conductors 51A and 51A closest to the other end side (X2 side) of the winding frame portion 32A. Similarly, the distances between the conductors 51A from the other end side (X2 side) to the one end side (X1 side) of the winding frame portion 32A are referred to as pitches P2, P3 ... Pn. The distance between the conductors 51A and 51A closest to one end side (X1 side) of the winding frame portion 32A is defined as Pn. Of course, the pitches P1 to Pn are the distances between the upper conductors 51A or the distances between the lower conductors 51A, but it goes without saying that they are not the distances between the adjacent upper conductors 51A and the lower conductors 51A.

Further, on the narrow surface (XZ surface) of the winding frame portion 32A, the distance between the adjacent conductors 51A and the conductors 51A is defined as pitch SP1, SP2 ... SPm. The pitch SP1 is the distance between the conductors 51A and 51A closest to the other end side (X2 side) of the winding frame portion 32A. Similarly, the distances between the conductors 51A from the other end side (X2 side) to the one end side (X1 side) of the winding frame portion 32A are referred to as pitch SP2, SP3 ... SPm. The distance between the conductors 51A and 51A closest to one end side (X1 side) of the winding frame portion 32A is defined as SPm. Here, as will be described later, on the side surface of the winding frame portion 32A (also referred to as a narrow surface or an XZ surface), the upper conductors 51A and the lower conductors 51A are alternately rearranged in the same plane, that is, in one layer, so that the pitch SP1 to 1 SPm is not the distance between the upper conductors 51A or the distance between the lower conductors 51A, but the distance between the adjacent upper conductors 51A and the lower conductors 51A.

Here, in the sparse winding portion 54A, the upper conductor wire 51A exists in a state of having a gap S1 outside the already existing lower layer conductor wire 51A. Therefore, in the sparse winding portion 54A, the inductance value is adjusted by moving the conducting wire 51A so as to narrow or widen the gap between the gaps S1 (either in the so-called pitches P1 to Pn or SP1 to SPm). It is possible to do.

In particular, it is most effective to be able to move the pitch P1 or SP1. The reason is that since the conducting wire 51A sandwiching the pitch P1 or SP1 is closest to the end of the core 20A, the influence on the distribution of the magnetic flux generated from the end of the core 20A is the largest. Similarly, the influence of the conductor 51A sandwiching the pitch P2 or SP2 is second. On the other hand, the conductor 51A sandwiching the pitch Pn or SPm has the least influence on the magnetic flux distribution, and generally does not move or change the pitch length. Therefore, the length of the pitch P1 is different from the length of the pitch Pn.

Further, in the fine adjustment of the inductance value, it is sufficient to move the first conductor 51A on the other end side (X2 side) of the winding frame portion 32A, so that only the pitch SP1 changes at this time, and the other pitch SP1 ~ SPm, or pitches P1 to Pn do not change. In other words, in this case, the length of the pitch SP1 is different from the pitch SPm, but the length of the pitch P1 is the same as the pitch Pn.

Further, as described above, in order to adjust the inductance value, the lengths of the pitches P1 to Pn or SP1 to SPm can be lengthened or shortened, but the length of each pitch can be shortened. preferable. That is, it is preferable that the length of the pitch P1 is shorter than the length of the pitch Pn, or the length of the pitch SP1 is shorter than the length of the pitch SPm.

Further, since the lower conductor 51A and the upper conductor 51A are wound in a crossed state, the upper conductor 51A is in a state where it can be easily moved with respect to the lower conductor 51A. There is. This situation is shown in FIGS. 6 and 7. FIG. 6 is an enlarged plan view showing the wound state of the lower-layer conductor 51A and the upper-layer conductor 51A in the antenna device 10A according to the present embodiment. FIG. 7 is an enlarged plan view showing the wound state of the lower layer conductor and the upper layer conductor in the antenna device as a comparative example.

As shown in FIG. 6, when the lower conductor 51A and the upper conductor 51A intersect (cross), the upper conductor 51A is less likely to fall into the recess between the adjacent lower conductors 51A. It slides while being placed on the lower conductor 51A. At this time, the upper conductor 51A slides in a state where the contact area is smaller than that of the lower conductor 51A.

On the other hand, as shown in FIG. 7, when the lower conductor 51A and the upper conductor 51A are wound in the same direction without intersecting with each other, the upper conductor 51A is located between the adjacent lower conductors 51A. It tends to be depressed in the dent. Further, the adjacent upper conductor wire 51A is also in a state of being depressed into a dent in the same manner. Therefore, when the upper conductor 51A is slid with respect to the lower conductor 51A, the dent to the top of the lower conductor 51A with respect to the target upper conductor 51A and the surrounding upper conductor 51A including the adjacent portion. It is necessary to lift it, and it is very difficult to slide it.

Next, the connection terminal 60A will be described. The connection terminal 60A shown in FIGS. 1 to 3 is formed by press-molding a metal terminal into a substantially L-shape. The connection terminal 60A is provided so that the appearance is substantially L-shaped. In order to form this substantially L-shape, the connection terminal 60A is bent so as to form a substantially right angle in the middle portion thereof. The substantially L-shaped connection terminal 60A is provided with an insertion piece portion 61A and a entwining portion 62A. Of these, the insertion piece portion 61A is a portion of the connection terminal 60A that extends in the width direction (Y direction) and protrudes into the connector hole of the connector connection portion 40A described above. Further, the entwined portion 62A is a portion extending in the vertical direction (Z direction). The entwined portion 62A is a portion where the terminal of the conducting wire 51A is entwined.

Further, the case 90A is a portion that covers the entire antenna device 10A, and is provided in a tubular shape that covers the coil 50A and the bobbin body 30A described above. The case 90A may have a mounting portion for mounting on an external device.

<Manufacturing method of antenna device 10A>
When manufacturing the antenna device 10A having the above configuration, the bobbin body 30A is formed by injection molding, and the connection terminal 60A is separately formed by press molding. Further, after the bobbin body 30A is formed, the connection terminal 60A is positioned at the terminal mounting portion 35A and inserted so as to protrude into the connector hole of the connector connection portion 40A (corresponding to the connection terminal insertion step).

Before and after this attachment, the core 20A is attached to the core insertion portion 34A (corresponding to the core insertion step). After the attachment, the lead wire 51A is wound around the winding frame portion 32A to form the coil 50A (corresponding to the coil forming step). In this coil forming step, when the lower conductor wire 51A is wound, the adjacent conductor wire 51A is wound up to the partition portion 33A in a state of being in close contact with each other. As a result, the dense winding portion 53A on the lower layer side is formed.

In a state of being continuous with the dense winding portion 53A on the lower layer side, the conductor 51A is wound on the other side (X2 side) in the longitudinal direction (X direction) from the partition portion 33A of the winding frame portion 32A, and the lead wire 51A is wound on the lower layer side. The sparse winding portion 54A is formed. In the case of forming the sparse winding portion 54A on the lower layer side, the winding is performed in a state where a relatively large gap S1 exists between the conducting wire 51A and the conducting wire 51A.

Then, after reaching the end of the winding frame portion 32A on the other side (X2 side) in the longitudinal direction (X direction), the partition portion 33A is in a winding direction opposite to that of the lower conductor 51A. The lead wire 51A is wound toward. Therefore, the upper conductor 51A is wound so as to intersect (cross) the lower conductor 51A.

Before and after the formation of the coil 50A as described above, one terminal of the conductor 51A is entwined with the tip end side of the entwining portion 62A of the one connection terminal 60A1. Further, the other terminal of the conductor 51A is entwined with the entwined portion 62A of the other connection terminal 60A2 after the coil 50A is formed. After those entanglements, the above-mentioned entangled portions are fixed by, for example, soldering by a dip method.

Here, it may be necessary to adjust the inductance value L after manufacturing the antenna device 10A. This inductance value L is obtained by the following equation.
L = k × μ ₀ × π × a ² × n ² / b… (1)
In the above equation (1), k is the Nagaoka constant, μ ₀ is the magnetic permeability, a represents the radius of the coil, n represents the number of turns, and b represents the coil length.

Here, when adjusting the inductance value L, in the sparse winding portion 54A, the lead wire 51A is shortened in the direction of shortening the coil length b (that is, shortening the pitch P1 to Pn and the pitch SP1 to SPm) by using a jig or the like. To move. That is, in the sparse winding portion 54A, the conducting wire 51A is slid in a direction in which the gap S1 at a predetermined portion is narrowed. Thereby, the inductance value L can be adjusted to be slightly larger. When a jig or the like is used, it is preferable that the sparse winding portion 54A is provided on the end side of the antenna device 10A. In other words, when the dense winding portion 53A is provided on the end side of the antenna device 10A and the sparse winding portion 54A is arranged between the dense winding portion 53A, the terminal mounting portion 35A, and the connector connecting portion 40A, the partition wall 35A2 Further, the frame wall and parts at the terminal mounting portion 35A and the connector connecting portion 40A may be an obstacle to the work, and the work may be difficult. In order to improve the work efficiency, it is preferable that the sparse winding portion 54A is provided on the end side of the antenna device 10A.

Further, in order to make fine adjustments, in the sparse winding portion 54A, it is preferable that the adjacent conducting wires 51A are adjacent to each other with a predetermined distance as much as possible between them. Therefore, in the X direction, the length of the sparse winding portion 54A is preferably longer than that of the dense winding portion 53A. Further, it is more preferable that the length of the sparse winding portion 54A is equal to the length of the dense winding portion.

<About the effect>
According to the antenna device 10A having the above configuration, the core 20A, the bobbin body 30A which is arranged on the outer peripheral side of the core 20A and the partition portion 33A exists in the middle of the longitudinal direction, and the lead wire 51A are connected to the bobbin body 30A. It includes a coil 50A formed by winding. Further, the coil 50A has a dense winding portion 53A formed by winding the winding density of the lead wire 51A from one side (X1 side) of the bobbin body 30A to the partition portion 33A in a dense state, and the partition portion 33A. A sparse winding portion 54A formed by winding the lead wire 51A in a sparse winding density to the other side (X2 side) of the bobbin body 30A is provided. Further, the sparse winding portion 54A is provided with a first layer (lower layer) and a second layer (upper layer), and the winding directions of the first layer and the second layer are different, so that the first layer can be formed. The conductors 51A constituting the second layer and the conductors 51A constituting the second layer are overlapped with each other in an intersecting state.

In this way, in the sparse winding portion 54A, the conductors 51A constituting the first layer (lower layer) and the conductors 51A constituting the second layer (upper layer) are overlapped with each other in an intersecting state. Has been done. Therefore, it becomes easy to slide the conductor 51A of the second layer (upper layer) with respect to the conductor 51A of the first layer (lower layer). Therefore, although the structure is simple, the inductance value can be easily adjusted.

Further, in the antenna device 10A, it is not necessary to use a separate magnetic material core such as a second magnetic material core as in the configuration disclosed in Patent Document 1, and further, the second magnetic material core wound around the second magnetic material core. There is no need to use two coils. Therefore, it is possible to simplify the structure for adjusting the inductance value.

Further, in the present embodiment, a terminal attachment portion 35A to which the other connection terminal 60A is attached is provided on one side (X1 side) of the bobbin body 30A, and the dense winding portion 53A is a sparse winding portion. It is provided on the terminal mounting portion 35A side of 54A. Therefore, the conductor 51A of the second layer (upper layer) can be easily slid.

That is, when the sparse winding portion 54A is provided on the terminal mounting portion 35A side with respect to the dense winding portion 53A, the sparse winding portion 54A is sandwiched between the terminal mounting portion 35A and the dense winding portion 53A. Therefore, the sparse winding portion 54A does not have a free end portion in the coil 50A. Therefore, it is difficult to slide the conductor 51A of the second layer (upper layer). On the other hand, when the dense winding portion 53A is provided on the terminal mounting portion 35A side with respect to the sparse winding portion 54A, the sparse winding portion 54A has a free end portion in the coil 50A. This makes it easier to slide the second layer (upper layer) lead wire 51A. Therefore, the inductance value can be easily adjusted.

Further, in the present embodiment, in the sparse winding portion 54A, the conductor wire 51A constituting the first layer (lower layer) and the conductor wire 51A constituting the second layer (upper layer) in the side wall portion 32A1 of the bobbin body 30A are the same. It is arranged so as to be located in one layer. That is, the conductor 51A constituting the first layer (lower layer) and the conductor 51A constituting the second layer (upper layer) are located in the same layer without being overlapped. Therefore, on the top surface 32A2 side and the bottom surface 32A3 side of the winding frame portion 32A, the distance between the conductors 51A in the first layer (lower layer) and the distance between the conductors 51A in the second layer (upper layer) can be secured relatively large. can. Therefore, it is possible to realize a configuration in which the inductance value can be easily adjusted.

Further, when the conductor wire 51A of the second layer (upper layer) is slid on the side wall portion 32A1, the conductor wire 51A of the adjacent first layer (lower layer) can also be slid on the slide exceeding the gap S1. Thereby, for example, it is possible to prevent the coil 50A from unwinding by sliding only the conductor wire 51A of the second layer (upper layer). Further, it is required that the position after sliding is fixed with respect to the coil 50A. Here, since the conductors 51A of the second layer and the first layer are in contact with the side wall portion 32A1, the winding force of the coil 50A and the frictional force between the conductors 51A and the side wall portion 32A1 cause an extra force. The position of the conductor 51A after sliding can be easily fixed without the need for a fixing structure.

Further, in the present embodiment, the conductor 51A of the first layer (lower layer) and the conductor 51A of the second layer (upper layer) are three degrees with respect to the width direction orthogonal to the longitudinal direction (X direction) of the bobbin body 30A. It intersects at an angle within the range of ~ 177 degrees. In this configuration, the conductor 51A of the second layer (upper layer) intersects with the conductor 51A of the first layer (lower layer) at an angle within the range of 6 degrees to 174 degrees. Therefore, it is possible to realize a configuration in which the conductor 51A of the second layer (upper layer) is easy to ride (easily cross) on the upper layer side of the conductor 51A of the first layer (lower layer).

Further, in the present embodiment, the length of the sparse winding portion 54A can be longer than the length of the dense winding portion 53A. In this case, in the sparse winding portion 54A, the distance between the conducting wires 51A can be provided by a predetermined distance or more, which facilitates fine adjustment of the inductance value L.

Further, in the present embodiment, the length of the sparse winding portion 54A can be made equal to the length of the dense winding portion 53A. In this case, the dense winding portion 53A can secure the inductance value L at a predetermined value or more, and the sparse winding portion 54A can make a fine adjustment of the inductance value L.

Further, in the present embodiment, in the longitudinal direction (X direction) of the bobbin body 30A, the distance between the adjacent conductors 51A located on the most opposite side (X2 side) is located on the most one side (X1 side). It is different from the distance between adjacent conductors 51A. Therefore, it is possible to move the conductor 51A located on the farthest side (X2 side) while not moving the conductor 51A located on the farthest side (X1 side). In this case, by moving only the conductor 51A on the othermost side (X2 side) close to the other end side (X2 side) of the core 20A, the influence on the distribution of the magnetic flux can be increased.

Further, in the present embodiment, in the longitudinal direction (X direction) of the bobbin body 30A, the distance between the adjacent conductors 51A located on the most opposite side (X2 side) is located on the most one side (X1 side). It can be provided shorter than the distance between adjacent conductors 51A. In this case, when the conductor 51A located on the farthest side (X2 side) is moved, the inductance value L can be finely adjusted.

(Second embodiment)
Hereinafter, the antenna device 10B according to the second embodiment of the present invention will be described with reference to the drawings. Although the description of the configuration common to the antenna device 10A in the above-described first embodiment is omitted in the present embodiment, the alphabet related to the first embodiment is added to the end of the reference numeral. The alphabet "B" shall be added instead of "A". The alphabet "B" has a configuration related to the second embodiment. Therefore, although not described or illustrated in the second embodiment, the same configuration as the antenna device 10A in the first embodiment may be described with the alphabet "B".

FIG. 8 is a perspective view showing the configuration of the antenna device 10B according to the second embodiment. FIG. 9 is a perspective view showing the configuration of the bobbin body 30B and the connection terminal 60B of the antenna device 10B shown in FIG. The terminal mounting portion 35B of the antenna device 10B of the present embodiment has a configuration different from that of the vicinity of the terminal mounting portion 35A of the antenna device 10A of the first embodiment described above. Further, the connector connection portion 40B of the antenna device 10B of the present embodiment has a different configuration from the connector connection portion 40A of the antenna device 10A of the first embodiment described above.

Specifically, the terminal mounting portion 35B is provided with a total of three connection terminals 60B, not a pair. Specifically, the connection terminals 60B1, 60B2, 60B3 exist. FIG. 10 is a plan view showing the shapes of the three connection terminals 60B1, 60B2, 60B3. As shown in FIG. 10, of the three connection terminals 60B, the connection terminal 60B1 is a connection terminal 60B1 located on the front side (Y1 side) in the width direction (Y direction). Further, the connection terminal 60B2 is located on the back side (Y2 side) in the width direction (Y direction) with respect to the connection terminal 60B1. Further, the connection terminal 60B3 is located on the other side (X2 side) in the longitudinal direction (X direction) from the connection terminal 60B1 and the connection terminal 60B2.

Here, the connection terminal 60B1 is provided with an insertion piece portion 61B, a entwining portion 62B, and a vertically extending portion 63B. The insertion piece portion 61B is a portion extending in the longitudinal direction (X direction), and is the same portion as the above-mentioned insertion piece portion 61A. Therefore, one side (X1 side) of the insertion piece portion 61B protrudes into the connector hole of the connector connection portion 40B and can be electrically connected to an external connector inserted into the connector hole.

Further, the entwining portion 62B is a portion in which one terminal of the conducting wire 51B is entwined, similarly to the entwining portion 62A described above. Further, the vertically stretched portion 63B is a portion stretched in the vertical direction (Z direction). Therefore, the positions of the insertion piece portion 61B and the entwining portion 62B are different in the height direction (Z direction).

Further, the connection terminal 60B2 is provided with an insertion piece portion 61B and a chip support piece portion 64B. The insertion piece portion 61B has the same configuration as the insertion piece portion 61B in the connection terminal 60B1. Further, the chip support piece portion 64B is a portion provided with a larger dimension in the width direction (Y direction) than the insertion piece portion 61B. Although both ends of the chip support piece portion 64B are inserted into the resin portion of the bobbin body 30A, the portion between both ends is exposed to the opening 35B1. One side of the chip-shaped capacitor 100B is attached to the chip support piece portion 64B in a state of being electrically connected.

Further, the connection terminal 60B3 is provided with a entwined portion 62B and a chip support piece portion 64B. The other terminal of the conducting wire 51B is entwined with the entwining portion 62B. Further, the other side of the capacitor 100B is attached to the chip support piece portion 64B in a state of being electrically connected.

Further, in the terminal mounting portion 35B, the connection terminal 60B is provided so as not to protrude upward (Z1 side) from the bottom surface 32B3 of the bobbin portion 31B. In order to have such a configuration, the bottom wall 35B3 of the terminal mounting portion 35B is provided to be thicker than the bottom surface 32B3. Then, a part of the connection terminals 60B1 to 60B3 described above is formed in the bottom wall 35B3 by, for example, insert molding, so that the connection terminals 60B1 to 60B3 are embedded in the bottom wall 35B3.

Here, in the bobbin body 30A of the antenna device 10A according to the first embodiment, a partition wall 35A2 that separates the terminal mounting portion 35A and the core insertion portion 34A is provided. However, the bobbin body 30B of the present embodiment is not provided with a configuration corresponding to such a partition wall. Further, as shown in FIG. 9, the connection terminal 60B does not protrude upward (Z1 side) from the bottom surface 32B3. Therefore, the core 20B can be moved to the terminal mounting portion 35B side.

The core 20B is inserted into the core by the core holding projection 32B6 and the inner wall of the bobbin portion 31B by winding the lead wire on the other end side (X2 side), similarly to the core 20A in the first embodiment described above. It is in a state of being held in the portion 34B.

Further, unlike the connector connecting portion 40A in the first embodiment, the connector connecting portion 40B is provided along the longitudinal direction (X direction). A flange portion 43B is provided at a portion that separates the terminal mounting portion 35B and the connector connection portion 40B. In the present embodiment, the flange portion 43B is provided in the shape of a rectangular plate, and a step portion 44B is provided on the outer peripheral edge portion of the flange portion 43B. The opening edge of the case 90A is fitted to the step 44B.

<About the effect>
The antenna device 10B according to the present embodiment can also exhibit the same effect as the antenna device 10A according to the first embodiment described above.

In addition, in the present embodiment, the bobbin body 30B does not have a configuration corresponding to the partition wall 35A2, and the connection terminal 60B does not protrude upward (Z1 side) from the bottom surface 32B3. Therefore, it is possible to slide it toward the terminal mounting portion 35B inside the core inserting portion 34B. Therefore, in addition to adjusting the inductance value by sliding the lead wire 51B of the first layer (upper layer) in the sparse winding portion 54B, the inductance value is increased or decreased by sliding the core 20B (slide in the sparse winding portion 54B). If this is not done, it is possible to make adjustments so as to reduce the inductance value in particular).

<Modification example>
Although each embodiment of the present invention has been described above, the present invention can be variously modified in addition to the above. This will be described below.

In the first embodiment described above, the electronic component is not attached between the pair of connection terminals 60A, but it may be attached. Further, in the second embodiment described above, the case where the capacitor 100B is attached as an electronic component is described, but another electronic component such as a resistor may be attached. The electronic component may be either a surface mount type or a pin type.

Further, in each of the above-described embodiments, the sparse winding portions 54A and 54B are located on the other side (X2 side) in the longitudinal direction (X direction), and the dense winding portions 53A and 53B are in the longitudinal direction (X direction). The case where it is located on one side (X1 side) is described. However, the configuration is not limited to this, and the sparse winding portions 54A and 54B are located on one side (X1 side) in the longitudinal direction (X direction), and the dense winding portions 53A and 53B are located in the longitudinal direction (X direction). It may be configured to be located on the other side (X2 side) of the above.

Further, a configuration may be adopted in which a plurality of sparse winding portions 54A and 54B are provided and the dense winding portions 53A and 53B are located between the sparse winding portions 54A and 54B. Further, a configuration may be adopted in which a plurality of dense winding portions 53A and 53B are provided and the sparse winding portions 54A and 54B are located between the dense winding portions 53A and 53B.

Further, in each of the above-described embodiments, the case where only one core 20A and 20B is present is described. However, there may be a plurality of cores. Further, the bobbin body may have any configuration as long as the dense winding portion and the sparse winding portion can be formed. Further, the number of connection terminals may be any number, and the configuration of the connection terminals may be any configuration.

10A, 10B ... Antenna device, 20A, 20B ... Core, 30A, 30B ... Bobbin body, 31A, 31B ... Bobbin part, 32A, 32B ... Winding frame part, 32A1, 32B1 ... Side wall part, 32A2, 32B2 ... Top surface, 32A3 , 32B3 ... bottom surface, 32A4, 32B4 ... punched part, 32A5, 32B5 ... slit, 32A6, 32B6 ... core holding protrusion, 33A, 33B ... partition part, 34A, 34B ... core insertion part, 35A, 35B ... terminal mounting part, 35A1 , 35B1 ... opening, 35A2 ... partition, 35B3 ... bottom wall, 40A, 40B ... connector connection, 41A ... partition wall, 42A ... terminal hole, 43B ... bobbin, 44B ... step, 50A, 50B ... coil, 51A, 51B ... Conductor wire, 53A, 53B ... Dense winding part, 54A, 54B ... Sparse winding part, 60A, 60A1, 60A2, 60B, 60B1, 60B2, 60B3 ... Connection terminal, 61A, 61B ... Plug-in piece part, 62A, 62B ... Tangled part, 63B ... Vertical extension part, 64B ... Chip support piece part, 90A ... Case, 100B ... Capacitor, S1 ... Gap

Claims (6)

A core made of magnetic material and
A square tubular winding frame portion having a wide wide surface in the outer peripheral direction and a narrow narrow surface in the outer peripheral direction is provided on the outer peripheral side of the core, and a partition portion is provided in the middle of the longitudinal direction. With the bobbin body in which
A coil formed by winding a conducting wire around the bobbin body,
Equipped with
The coil has a dense winding portion formed by winding the winding density of the conducting wire from one side of the bobbin body to the partition portion in a dense state, and the other of the bobbin body from the partition portion. A sparse winding portion formed by winding the lead wire in a sparse state is provided up to the side.
The sparse winding portion is provided with a first layer and a second layer, and the winding directions of the first layer and the second layer are different from each other, thereby forming the first layer. The conductor and the conductor constituting the second layer are overlapped with each other in an intersecting state.
Regarding the distance between the adjacent conductors constituting the sparsely wound portion on the wide surface, the distance located on the one-sided side from the distance located on the most opposite side of the bobbin body is set to pitch P1 to Pn (pitch P1 to Pn). However, n is an integer of 2 or more), and the distance between the adjacent conductors constituting the sparse winding portion on the narrow surface is the largest from the distance located on the farthest side of the bobbin body. When the interval located on one side is pitch SP1 to SPm (where m is an integer of 2 or more), (a) the length of the pitch P1 is the length of all the remaining pitches except the pitch P1. Different from the length, or (b) the length of the pitch SP1 is different from the length of all the remaining pitches except the pitch SP1.
An antenna device (except when the antenna device includes, in addition to the core, a sub-core that can move in a direction orthogonal to the winding direction of the coil) . The antenna device according to claim 1.
An antenna device characterized in that the length of the pitch P1 is larger than the length of all the remaining pitches except the pitch P1. The antenna device according to claim 1.
An antenna device characterized in that the length of the pitch SP1 is larger than the length of all the remaining pitches except the pitch SP1. It is provided with a square tubular winding frame portion having a wide wide surface in the outer peripheral direction and a narrow narrow surface in the outer peripheral direction, and is magnetically attached to the core insertion portion of the bobbin body having a partition portion in the middle of the longitudinal direction. The core insertion process of inserting the core formed from the material,
A coil forming step of winding a conducting wire around the bobbin body to form a coil,
A conductor moving step of moving the conductors constituting the coil in the longitudinal direction of the bobbin body,
Equipped with
In the coil forming step, the dense winding portion formed by winding the winding density of the conducting wire from one side of the bobbin body to the partition portion in a dense state, and the bobbin body from the partition portion. A sparse winding portion formed by winding the lead wire in a sparse state to the other side is formed.
In the sparsely wound portion, after winding the first layer, the second layer having a winding direction different from that of the first layer is wound to form the first layer and the conductor. It intersects with the conductor that constitutes the second layer, and
In the wire moving step, (a) among the conductors constituting the sparsely wound portion, the conductors located on the wide surface and on the outermost side of the bobbin body, or (b) the sparsely wound portion is configured. Of the conducting wires to be used, the conducting wire located on the narrow surface and on the outermost side of the bobbin body is moved to one side or the other side of the bobbin body.
A method for manufacturing an antenna device (except when the antenna device includes, in addition to the core, a sub-core that can move in a direction orthogonal to the winding direction of the coil) . The method for manufacturing an antenna device according to claim 4.
In the wire moving step, (a) among the conductors constituting the sparse winding portion, the conductor located on the wide surface and on the outermost side of the bobbin body is moved to the other side of the bobbin body. A method of manufacturing a characteristic antenna device. The method for manufacturing an antenna device according to claim 4.
In the wire moving step, (b) among the conductors constituting the sparse winding portion, the conductor located on the narrow surface and on the outermost side of the bobbin body is moved to the other side of the bobbin body. A method for manufacturing an antenna device.

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