JP2017200149A - Antenna device and method for manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antenna device arranged to be able to suppress the fluctuation in Q value, which is attributed to the change in temperature even with a simple structure, and provide a method for manufacturing the antenna device.SOLUTION: An antenna device 10A comprises a core 20A, and flat plate-like eddy current-generating means disposed on an outer peripheral side of a coil 50A. On condition that the antenna device includes the coil 50A without the eddy current-generating means, a first Q value showing the sharpness of a peak of resonance caused by the coil 50A decreases with the rise in temperature based on a temperature change of a resistance value of a conducting wire 51A. On condition that the antenna device includes the eddy current-generating means, a second Q value showing the sharpness of a peak of resonance by the eddy current-generating means increases with the rise in temperature because of current fluctuation corresponding to a temperature change of a resistance value of the eddy current-generating means. A rate of change to a temperature rise of an adjustment Q value showing the sharpness of a peak of resonance based on the coil 50A and the eddy current-generating means is smaller than a rate of change to a temperature rise of the first Q value, and that of the second Q value.SELECTED DRAWING: Figure 1

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 to practical use in vehicles such as automobiles and houses. This smart key system transmits / receives information related to a wireless ID code or the like as an electromagnetic wave, and when the ID code or the like is collated, without using a mechanical key, for example, locking a door in a vehicle or a house, It is possible to unlock and to start and stop the engine. In such a smart key system, an antenna device including a coil antenna is used to transmit and receive information.

  In recent years, such an antenna device has been required to have a wide band capable of transmitting and receiving stable radio signals in a wide frequency band. In this case, by setting a wide allowable characteristic range for transmission / reception of radio signals, even if the characteristics of individual antenna devices vary, the allowable range is within the allowable range. Thereby, the simplification of design and the degree of freedom related to the manufacture of the antenna device can be improved.

  As this antenna device, there is one disclosed in Patent Document 1. Patent Document 1 discloses a technique related to a communication device used in a keyless entry system. This communication apparatus changes the code length of a spread code used for spread spectrum and varies the Q value of the antenna in accordance with the noise situation in the usage environment. Thereby, long-range communication in a narrow band and short-range communication in a wide band are realized with the same antenna.

JP 2008-258817 A

  By the way, according to the technical content disclosed in Patent Document 1, the variation of the Q value of the antenna device is realized by changing the resistance value of the antenna resonance circuit. However, in the configuration in which resistance elements are connected in series to the antenna device, if the resistance value is increased to satisfy a desired Q value, the circuit structure may be complicated. In addition, the vehicle body is often different for each vehicle type, but in order to select a Q value suitable for the vehicle body, it is necessary to use resistance elements having various resistance values. Accordingly, inventory management of parts becomes complicated and the cost increases. Therefore, an antenna device having a desired Q value with a simple configuration is desired.

  In addition, when a temperature change occurs during use of the antenna device, there is a possibility that the Q value may fluctuate. Thus, when the Q value fluctuates due to a temperature change, there is a problem that separate adjustment may be necessary in the entire system in which the antenna device is installed.

  The present invention has been made in view of this problem, and an object of the present invention is to provide an antenna device and an antenna device that can suppress variation in the Q value depending on a temperature change while having a simple configuration. It is going to provide the manufacturing method of this.

  In order to solve the above problems, one aspect of the antenna device of the present invention includes a core formed of a magnetic material, a coil formed by winding a conductor around the core and the outer periphery of the coil, and an outer periphery of the core. Plate-like eddy current generating means disposed on the side, and when there is no eddy current generating means and a coil is provided, a Q value (first Q value) representing the sharpness of resonance peak due to the coil Is reduced with increasing temperature based on the temperature change of the resistance value of the conducting wire, and in the case where the eddy current generating means is provided, the Q value (the second Q value and the second Q value) represents the sharpness of the resonance peak by the eddy current generating means. Is increased as the temperature rises due to a current fluctuation corresponding to the temperature change of the resistance value of the eddy current generating means, and a Q value (adjusted Q value) indicating the sharpness of the resonance peak based on the coil and the eddy current generating means. The antenna device is characterized in that the rate of increase / decrease in temperature rise is smaller than the rate of increase / decrease in temperature rise of the first Q value and the rate of increase / decrease in temperature rise of the second Q value. The

  In addition to the above-described invention, another aspect of the antenna device according to the present invention is a winding portion formed by winding a film-like member having a nonmagnetic metal layer. It is preferable that there is.

  Furthermore, the other side surface of the antenna device of the present invention is a copper tape provided with a copper foil layer in addition to the above-described invention, and the winding portion is formed by winding the copper tape. It is preferable that it is a copper tape winding part.

  Further, in another aspect of the antenna device of the present invention, in addition to the above-described invention, it is preferable that the winding portion is located at a portion near both ends in the longitudinal direction of the core.

  Furthermore, in another aspect of the antenna device of the present invention, in addition to the above-described invention, the conductive wire constituting the coil is further compared with the case where the resistance element is connected in series to the series resonance circuit including the coil. The diameter is preferably reduced so as to have at least a part of the resistance value of the resistance element.

  Further, in another aspect of the antenna device of the present invention, in addition to the above-described invention, it is preferable that the diameter of the conducting wire is 0.1 mm or less.

  Furthermore, the other side surface of the antenna device of the present invention is disposed on the core formed from a magnetic material, a coil formed by winding a conducting wire around the outer periphery of the core, and the outer periphery of the core and the coil. An interval maintaining unit for defining an interval with the eddy current generating means, and when the coil is provided while the eddy current generating means is not present, a Q value (first Q value) representing the sharpness of the resonance peak due to the coil Is a Q value (second Q value) that represents the sharpness of the resonance peak caused by the eddy current generating means when the eddy current generating means is present and decreases with increasing temperature based on the temperature change of the resistance value of the conducting wire. Is increased as the temperature rises due to the current fluctuation corresponding to the temperature change of the resistance value of the eddy current generating means, and the Q value (adjustment) representing the sharpness of the resonance peak based on the coil and the eddy current generating means The antenna device is characterized in that the rate of increase / decrease in temperature rise is smaller than the rate of change in temperature rise of the first Q value and the rate of increase / decrease in temperature rise of the second Q value. Provided.

  One aspect of the method for manufacturing an antenna device of the present invention includes 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 part in the middle in the longitudinal direction, and a bobbin body A coil forming step of forming a coil by winding a conducting wire, and a winding portion forming step of forming a winding portion by winding a film-like member having a nonmagnetic metal layer on the outer peripheral side of the core. In the case where the coil is provided while the winding portion does not exist, the Q value (first Q value) indicating the sharpness of the resonance peak due to the coil is a temperature based on the temperature change of the resistance value of the conducting wire. In the case where the winding portion is reduced and the winding portion is provided, the Q value (the second Q value) representing the sharpness of the resonance peak by the winding portion corresponds to the temperature change of the resistance value of the winding portion. Increase with temperature rise due to current fluctuation The increase / decrease rate in the temperature rise of the Q value (adjusted Q value) representing the sharpness of the resonance peak based on the coil and the winding portion is the increase / decrease rate in the temperature rise of the first Q value and the increase / decrease in the temperature rise of the second Q value. There is provided a method of manufacturing an antenna device, characterized in that the winding portion is formed so as to be smaller than the rate.

  According to the present invention, although the antenna device has a simple configuration, it is possible to suppress a change in the Q value due to a temperature change.

1 is a perspective view showing an overall configuration of an antenna device according to a first embodiment of the present invention. It is a perspective view which shows the state which removed the coil among the antenna apparatuses shown in FIG. It is side surface sectional drawing which shows the structure of the antenna apparatus shown in FIG. It is a perspective view which shows the structure of the bobbin body of the antenna apparatus shown in FIG. It is a top view which shows the part by which the coil is wound among the bobbin parts of the antenna apparatus shown in FIG. It is a top view which expands and shows the winding state of the conducting wire of the lower layer and the conducting wire of the upper layer in the antenna device which concerns on this Embodiment. It is a top view which expands and shows the winding state of the lower conducting wire and the upper conducting wire in the antenna apparatus as a comparative example. It is a figure which shows the relationship between Q value and temperature which concerns on each embodiment of this invention. It is a perspective view which shows the structure of the antenna apparatus which concerns on the 2nd Embodiment of this invention. It is a perspective view which shows the structure of the bobbin body and connection terminal of the antenna apparatus shown in FIG. It is a top view which shows the shape of three connection terminals with which the antenna apparatus shown in FIG. 9 is provided. It is a sectional side view which shows the antenna apparatus which concerns on the 3rd Embodiment of this invention.

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

  Moreover, in the following description, it may be described using an XYZ orthogonal coordinate system. Of these, the X direction is the longitudinal direction of the antenna device 10A, the X1 side is the side where a connector connecting portion 40A described later is located, and the X2 side is the opposite side. 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 (width direction) orthogonal to the XZ direction, the Y1 side is the right front side in FIG. 1, and the Y2 side is the back left side opposite to that.

<About 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 where 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 includes a core 20A, a bobbin body 30A, a coil 50A, a connection terminal 60A, a copper tape winding part 70A, and a case 90A as main components. It is said.

  As shown in FIGS. 2 and 3, the core 20 </ b> A is formed of a magnetic material and is provided in a long shape (bar shape) that is long in the X direction. The core 20A has a rectangular cross section when viewed from the front. The core 20A is made of a magnetic material. Examples of the magnetic material include various magnetic materials such as nickel-based ferrite or manganese-based ferrite, permalloy, sendust, and various magnetic materials and various magnetic materials. It is possible to use a mixture of materials.

  Moreover, as shown in FIG. 2, the bobbin part 31A of the bobbin body 30A is attached to the outer peripheral side of the core 20A. The bobbin body 30A is preferably made of a thermoplastic resin or a thermosetting resin excellent in insulation. An example of the material constituting the bobbin body 30A is PBT (polybutylene terephthalate), but other resins may be used as the material. The bobbin body 30A is more preferably made of a heat resistant resin in view of the fact that it may be subject to thermal damage due to soldering or welding.

  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 attachment portion 35A, and a connector connection 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 reel portion 32A may have a cylindrical shape, but in the present embodiment, it is provided in a suitably punched shape. Specifically, as shown in FIG. 4, punched portions 32A4 and slits 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 a configuration to provide. In particular, the slit 32A5 is provided on the other end side (X2 side) in the longitudinal direction (X direction). The other end side (X2 side) of the slit 32A5 is open. Therefore, when the conducting wire 51A is wound around the winding frame portion 32A in a state where a predetermined tension is applied, the core 20A inserted into the core insertion portion 34A is tightened to partially hold the core 20A.

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

  The core insertion portion 34A is a hole-like 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 contacts the core 20A is provided on the inner wall side of the side wall 32A1 facing the core insertion portion 34A. Any number of the core holding protrusions 32A6 may be provided. However, in the configuration illustrated in FIG. 4, the core holding protrusions 32A6 are provided on a portion (X1 side) closer to the longitudinal direction (X direction) of the core insertion portion 34A. 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 formed by winding the conducting wire on the other end side (X2 side).

  Further, the terminal attachment portion 35A is a portion to which the connection terminal 60A (see FIGS. 1 and 2) is attached. The terminal mounting portion 35A is provided with an opening portion 35A1 penetrating in the vertical direction, and the binding portion 62A of the pair of connection terminals 60A is exposed to the opening portion 35A1. The ends of the conductors 51A of the coil 50A are entangled with the binding portions 62A. After the entanglement, the coils 50A and the connection terminals 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 attachment portion 35A in order to separate the terminal attachment portion 35A and the core insertion portion 34A. The core 20A is positioned in the core insertion portion 34A when the core 20A hits against the partition wall 35A2.

  Here, it is good also as a structure which attaches the board | substrate which mounts a capacitor | condenser, resistance, etc., for example to 35 A of terminal attachment parts. When the substrate is attached, a part of the connection terminal 60A such as the binding portion 62A penetrates the substrate and is soldered at the penetrated portion, so that the conductor pattern of the substrate and the connection terminal 60A are electrically connected. Connected. In addition, when attaching a board | substrate to the terminal attachment part 35A, it is preferable to set it as the structure by which a board | substrate is fitted with respect to the terminal attachment part 35A.

  Further, the connector attachment portion 40A is continuously provided in the terminal attachment portion 35A. In the present embodiment, connector connecting portion 40A is provided along the width direction (Y direction) orthogonal to the longitudinal direction (X direction). The connector connecting 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 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 the present embodiment, since a pair of connection terminals 60A are provided, a pair of terminal holes 42A are also present. However, the number of terminal holes 42A can be changed as appropriate according to the number of connection terminals 60A.

  In addition, an external connector that is inserted into the connector hole is electrically connected to the connection terminal 60A protruding inside the connector hole. Thereby, it is possible to conduct current to a 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, a coil 50A is formed by winding a conducting wire 51A around a winding frame portion 32A. In the present embodiment, the conducting wire 51A has a smaller diameter than the conducting wire used in the conventional antenna device. Specifically, in the conventional antenna device, when the diameter of 0.26 mm is an appropriate conductor diameter, the conductor 51A is significantly smaller in size than the appropriate diameter, and the diameter is 0.08 mm. There is something to do. When this small-diameter conducting wire 51A is used, at least part of the resistance value of the resistance element (100% resistance value) as compared with the configuration in which the resistance element is connected in series to the series resonance circuit including the core (conventional configuration). However, the diameter is reduced so as to have a resistance value smaller than that, but may be larger than that of a coil wire of a conventional configuration.

  Note that the conductive wire 51A having a small diameter is not limited to 0.08 mm in diameter, and may have any value as long as the diameter is smaller than that of the conventional antenna device. For example, when the diameter of the conventional antenna device is sufficiently larger than 0.26 mm, the diameter of the conducting wire 51A may be 0.26 mm or less, but may exceed 0.26 mm. In addition, as a preferable diameter of conducting wire 51A, it may be 0.1 mm or less, for example.

Here, the antenna device 10A may have a configuration in which the copper tape winding portion 70A exists, but may have a configuration in which the copper tape winding portion 70A does not exist. In the case of a configuration in which the copper tape winding part 70A does not exist, the Q value and the L value are obtained by the following expressions (1) and (2).
Q = (1 / R) × (√L / C) (1)
L = k × μ ₀ × π × a ² × n ² / b Formula (2)
Here, k is the Nagaoka constant, μ ₀ is the magnetic permeability, n ² is the square of the radius of the coil, n ² is the square of the number of turns of the coil, and b is the length of the coil.

  From the above formulas (1) and (2), in the antenna device 10A, in the configuration in which the copper tape winding portion 70A does not exist, by reducing the diameter of the conducting wire 51A, the inductance equal to or higher than that of the conventional antenna device is obtained. While securing the value L, the Q value representing the sharpness of the resonance peak can be lowered according to the system in which the antenna device 10A is incorporated. Such adjustment that lowers the Q value is realized by mounting a resistance element as disclosed in Patent Document 1 in the conventional configuration. However, in the present embodiment, the Q value can be lowered without mounting a resistance element.

  As shown in FIG. 5, the coil 50A is provided with a densely wound portion 53A and a sparsely wound portion 54A. The densely wound portion 53A is a portion of the coil 50A that is wound around one side (X1 side; terminal attachment portion 35A side) in the longitudinal direction (X direction) of the winding frame portion 32A. On the other hand, the sparse winding part 54A is a part wound around the partition part 33A from the partition part 33A to the other side (X2 side) in the longitudinal direction (X direction) of the winding frame part 32A. .

  In the configuration shown in FIG. 5, the densely wound portion 53A and the sparsely wound portion 54A have a configuration in which the conductive wire 51A is wound in two layers. For example, one end side in the longitudinal direction (X direction) of the winding frame portion 32A ( Winding is started from the (X1 side), and after reaching the other end side (X2 side) of the winding frame portion 32A, it reaches the other end side (X1 side) while being wound again. Accordingly, the lower layer (first layer) conducting wire 51A and the upper layer (second layer) conducting wire 51A intersect (cross) each other. However, the densely wound portion 53A and the sparsely wound portion 54A are not limited to the two-layer winding, and may be wound in several layers such as four or six layers.

  Note that the other end side (X2 side) of the winding frame part 32A may be configured to include a locking means for shifting and holding the conductor 51A. By this locking means, the conductive wire 51A is locked on the other end side (X2 side) of the winding frame portion 32A, so that the lower layer (first layer) conductive wire 51A and the upper layer (second layer) conductive wire 51A are connected. A state of crossing (crossing) well may be realized. Further, the lower layer (first layer) conducting wire 51A and the upper layer (second layer) conducting wire 51A are 3 degrees to the width direction (Y direction) orthogonal to the longitudinal direction (X direction) of the bobbin body 30A. It can be set as the structure which cross | intersects at the angle within the range of 177 degree | times. Within this angle range, the upper layer (second layer) conductor 51A does not have to fall into the recesses between the adjacent lower layer (first layer) conductors 51A, and the inductance value is adjusted. It will be easy to perform.

  As is clear from FIG. 5, the sparse winding part 54A is a part having a lower winding density than the dense winding part 53A. That is, the number of turns of the conducting wire 51A per unit length in the sparsely wound portion 54A is smaller than that of the densely wound portion 53A. Accordingly, in the sparsely wound portion 54A, a relatively large gap S1 exists between the adjacent conducting wires 51A and 51A.

  Here, in the sparse winding part 54A, the upper conductive wire 51A is present outside the existing lower conductive wire 51A in a state having a gap S1. Therefore, in the sparse winding part 54A, it is possible to adjust the inductance by moving the conducting wire 51A so as to narrow the gap S1.

  Further, since the lower conductor 51A and the upper conductor 51A are wound in a crossing (crossing) state, the upper conductor 51A is easily moved relative to the lower conductor 51A. Yes. This is shown in FIG. 6 and FIG. FIG. 6 is an enlarged plan view showing a winding state of the lower conductive wire 51A and the upper conductive wire 51A in the antenna device 10A according to the present embodiment. FIG. 7 is an enlarged plan view showing a winding state of a lower conductor and an upper conductor in an 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 conductive wire 51A. At this time, the upper conductor 51A slides with a lower contact area with respect to the lower conductor 51A.

  On the other hand, as shown in FIG. 7, when the lower conductor 51 </ b> A and the upper conductor 51 </ b> A are wound in the same direction without intersecting, the upper conductor 51 </ b> A is between the adjacent lower conductors 51 </ b> A. It tends to become depressed. And the adjacent upper layer conducting wire 51A is also in a state of falling into the recess. Therefore, when the upper layer conductor 51A is slid with respect to the lower layer conductor 51A, the upper layer conductor 51A as a target and the upper layer conductor 51A in the surrounding area including the adjacent portion are moved from the recess to the top of the lower layer conductor 51A. It is necessary to lift up and it is in a state that is very difficult to slide.

  The coil 50A is not limited to such a configuration. For example, it is good also as a structure in which only the dense winding part 53A exists. Further, the coil 50A may be configured such that only the sparse winding part 54A exists.

  Next, the connection terminal 60A will be described. The connection terminal 60A shown in FIGS. 1 to 3 is formed by pressing 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 part thereof. Such an approximately L-shaped connection terminal 60A is provided with an insertion piece portion 61A and a binding portion 62A. Among these, the insertion piece portion 61A is a portion extending in the width direction (Y direction) of the connection terminal 60A, and is a portion protruding into the connector hole of the connector connection portion 40A described above. Further, the binding portion 62A is a portion extending in the vertical direction (Z direction). The binding portion 62A is a portion where the end of the conducting wire 51A is bound.

  Next, the copper tape winding part 70A will be described. The copper tape winding part 70A corresponds to the eddy current generating means and the winding part. The copper tape winding portion 70A is a portion formed by winding a copper tape having a copper foil layer around the outer periphery of the coil 50A. In addition, a copper tape respond | corresponds to a film-form member provided with a metal layer. As shown in FIG. 1, in the antenna device 10A of the present embodiment, the copper tape winding portion 70A covers the outer peripheral side of the coil 50A at a portion near both ends in the longitudinal direction (X direction) of the core 20A. It is attached. When this configuration is employed, the Q value itself is reduced as compared with a configuration in which the copper tape winding portion 70A does not exist, but it is possible to increase the bandwidth.

  In addition, the site | part close | similar to the both ends of the longitudinal direction (X direction) of the core 20A may be a site including both ends of the core 20A.

  By the way, the vicinity of both ends in the longitudinal direction (X direction) of the core 20A is a portion where the magnetic flux passing through the inside of the core 20A goes out. Therefore, when the copper tape winding part 70A exists near both ends of the core 20A, an eddy current is generated in the copper tape winding part 70A by the magnetic flux.

  Here, when an eddy current is generated, a temperature rise occurs in the copper tape winding part 70A. Here, in a conductor made of copper, as the temperature rises, the resistance increases. Therefore, when a temperature rise occurs in the copper tape winding part 70A, it becomes difficult for current to flow in accordance with the temperature rise. Therefore, the eddy current is reduced and the eddy current loss is reduced. On the other hand, the Q value is higher when the eddy current loss is smaller than when the eddy current loss is large.

  Here, in antenna device 10A, while providing copper tape winding part 70A, conducting wire 51A considers the same composition as before (corresponding to antenna device 12A mentioned below). In this case, the eddy current loss decreases due to the increase in resistance of the copper tape winding part 70A accompanying the temperature rise, and the Q value increases accordingly. On the other hand, in the antenna device 10A, a configuration in which the coil 50A is formed by the conductive wire 51A having a small diameter as described above but the copper tape winding portion 70A does not exist is considered (corresponding to the antenna device 11A described later). In this case, since the resistance of the conducting wire 51A increases due to the temperature rise, the Q value becomes smaller than the equation (1).

  Here, in the antenna device 10A, the coil 50A is formed by the conductive wire 51A having a small diameter, and the copper tape winding portion 70A is present near both ends in the longitudinal direction (X direction) of the core 20A. FIG. 8 shows the temperature change of the Q value at this time. FIG. 8 is a diagram showing the relationship between the Q value and the temperature. In FIG. 8, the change in the Q value (corresponding to the adjustment Q value) in the antenna device 10A of the present embodiment is indicated by a solid line. In addition, a change in Q value (corresponding to the first Q value) in the antenna device 11A in which the coil 50A is formed by the conductive wire 51A having a small diameter but the copper tape winding portion 70A does not exist is indicated by a one-dot chain line. In addition, while the copper tape winding portion 70A is provided, a change in Q value (corresponding to the second Q value) in the antenna device 12A equivalent to that of the conventional conductor 51A is indicated by a two-dot chain line.

  As shown in FIG. 8, in the antenna device 10A of the present embodiment, the Q value changes in a state where the Q values indicating temperature changes are added together as in the antenna device 11A and the antenna device 12A. Therefore, in the antenna device 10A, even if the temperature rises, the Q value is hardly changed, or the Q value varies less than the Q value variation in the antenna device 11A and the antenna device 12A. be able to.

  Note that the Q value indicated by the solid line in FIG. 8 can be adjusted according to the position where the copper tape winding portion 70A is attached and the area of the copper tape winding portion 70A, and the diameter of the conducting wire 51A is selected. It is also possible to adjust by.

  Further, in the state shown in FIG. 8, with reference to the Q value at 20 degrees, the fluctuation range is within ± 3% within the practical temperature range of −40 degrees to +85 degrees. However, the fluctuation range in the above-described temperature range only needs to be within ± 10%.

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

<Regarding Method for Manufacturing Antenna Device 10A>
When manufacturing the antenna device 10A having the above configuration, the bobbin body 30A is formed by injection molding, and the core 20A is formed by press molding. Further, after the bobbin body 30A is formed, the connection terminal 60A is positioned at the terminal attachment portion 35A and inserted so as to protrude into the connector hole of the connector connection portion 40A (corresponding to the core insertion step).

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

  In a state continuous with the dense winding portion 53A on the lower layer side, the conductive wire 51A is wound on the other side (X2 side) in the longitudinal direction (X direction) of the partition portion 33A in the winding frame portion 32A, The sparse winding part 54A is formed. In the case of forming the sparsely wound 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 portion on the other side (X2 side) in the longitudinal direction (X direction) of the winding frame portion 32A, the partition portion 33A is in a state where the winding direction is opposite to that of the lower conductive wire 51A. The conducting wire 51A is wound toward the front. Accordingly, the upper conductive wire 51A is wound in a state of intersecting (crossing) the lower conductive wire 51A.

  Before and after the formation of the coil 50A as described above, one end of the conducting wire 51A is entangled with the distal end side of the linking portion 62A of the one connection terminal 60A1. The other end of the conducting wire 51A is entangled with the entangled portion 62A of the other connection terminal 60A2 after the formation of the coil 50A. After the entanglement, the above-described entangled portion is fixed by, for example, dip soldering.

  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 above-described equation (2). When adjusting the inductance value L, the conductive wire 51A is moved in the direction of shortening the coil length b in the sparse winding portion 54A. That is, in the sparsely wound 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 increased.

  Further, before and after the adjustment of the inductance value L, the copper tape winding part 70A is formed by winding the copper tape around the outer periphery of the coil 50A (corresponding to the winding part forming step). The copper tape winding portion 70A is formed so as to cover the outer peripheral side of the coil 50A in the vicinity of both ends in the longitudinal direction (X direction) of the core 20A. However, the position where the copper tape winding part 70A is formed may be changed as appropriate. As described above, the antenna device 10A is formed.

  Further, after the above-described steps are completed, the bobbin body 30A and the coil 50A are inserted into the case 90A. At this time, an adhesive may be applied to contact portions of the case 90A, the bobbin body 30A, and the coil 50A to bond them.

<About effect>
According to the antenna device 10A having the above configuration, when the coil is provided while the copper tape winding portion 70A does not exist (corresponding to the antenna device 11A), the Q value representing the sharpness of the resonance peak by the coil 50A. The (first Q value) decreases with increasing temperature based on the temperature change of the resistance value of the conducting wire 51A. In the case where the copper tape winding part 70A is provided, the Q value (second Q value) representing the sharpness of the resonance peak by the copper tape winding part 70A is a temperature change of the resistance value of the copper tape winding part 70A. It increases with temperature rise due to current fluctuation corresponding to. The rate of increase / decrease in the temperature rise of the Q value (adjusted Q value) representing the sharpness of the resonance peak based on the coil 50A and the copper tape winding portion 70A is the rate of increase / decrease in the temperature rise of the first Q value and the second Q value. It is provided to be smaller than the rate of increase / decrease in the temperature rise.

  For this reason, it is possible for the antenna device 10 </ b> A to suppress a change in the Q value (adjusted Q value) due to a temperature change, even though it has a simple configuration. In particular, since the variation of the Q value can be suppressed in an environment where temperature change is likely to occur, such as in-vehicle use, the performance of the antenna device 10A can be stabilized.

  In the present embodiment, the eddy current generating means is a copper tape winding portion 70A formed by winding a copper tape having a copper foil layer corresponding to the sheet-like member. For this reason, it is possible to satisfactorily suppress the temperature rise of the Q value (adjusted Q value) by utilizing the physical property of copper that the resistance increases as the temperature rises.

  In this embodiment, copper tape winding part 70A is located in the part near both ends of the longitudinal direction (X direction) of core 20A. Therefore, since the copper tape winding part 70A exists near the magnetic flux passing through the inside of the core 20A, the eddy current can be generated in the copper tape winding part 70A. And an eddy current becomes difficult to flow by making internal resistance increase by the temperature rise in 70 A of copper tape winding parts. Therefore, while providing a copper tape winding portion 70A as shown by a two-dot chain line in FIG. 8, the Q value is improved as the temperature rises as the conductive wire 51A has a Q value in the antenna device 12A equivalent to the conventional one. Can be reduced. As a result, the antenna device 10A can satisfactorily suppress the variation in the Q value (adjusted Q value) due to the temperature change, even though the antenna device 10A has a simple configuration.

  Furthermore, in the antenna device 10A of the present embodiment, the conductive wire 51A constituting the coil 50A has a resistance of the resistance element as compared with the configuration in which the resistance element is connected in series to the series resonance circuit including the core (conventional configuration). The diameter is reduced to have at least a portion of the value. Therefore, in antenna apparatus 10A of the present embodiment, variation in Q value is suppressed by coil 50A and copper tape winding portion 70A so that the Q value (adjusted Q value) indicated by the solid line in FIG. It becomes possible.

  Moreover, in this Embodiment, the diameter of 51 A of conducting wires can be provided in 0.1 mm or less. Thus, in antenna apparatus 10A of the present embodiment, the diameter of conductive wire 51A is reduced to 0.1 mm without mounting a resistance element (the conventional configuration is 0.26 mm, for example). Since the internal resistance is increased, the Q value (first Q value) can be satisfactorily reduced, and the bandwidth of the antenna device 10A can be increased. In addition, since the conductive wire 51A has the resistance value of the resistance element, it is not necessary to mount the resistance element, the process can be simplified correspondingly, and inventory management of the resistance element is not required. .

(Second Embodiment)
Hereinafter, an antenna device 10B according to a second embodiment of the present invention will be described with reference to the drawings. In the present embodiment, the description of the configuration common to the antenna device 10A in the first embodiment described above is omitted, but the alphabet related to the first embodiment is added at the end of the reference numeral. The alphabet “B” is attached instead of “A”. Note that the alphabet “B” has a configuration related to the second embodiment. Therefore, although not described and illustrated in the second embodiment, the same configuration as that of the antenna device 10A in the first embodiment may be described with an alphabet “B”.

  FIG. 9 is a perspective view showing a configuration of an antenna apparatus 10B according to the second embodiment. FIG. 10 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 different configuration from the vicinity of the terminal mounting portion 35A of the antenna device 10A of the first embodiment described above. Further, the connector connecting portion 40B of the antenna device 10B of the present embodiment has a different configuration from the connector connecting 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 instead of a pair. Specifically, connection terminals 60B1, 60B2, and 60B3 exist. FIG. 11 is a plan view showing the shapes of the three connection terminals 60B1, 60B2, and 60B3. As shown in FIG. 11, among 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. Furthermore, the connection terminal 60B3 is located on the other side (X2 side) in the longitudinal direction (X direction) than the connection terminal 60B1 and the connection terminal 60B2.

  Here, the connecting terminal 60B1 is provided with an insertion piece portion 61B, a binding 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 insertion piece portion 61A described above. 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 binding portion 62B is a portion where one end of the conducting wire 51B is bound, similarly to the binding portion 62A described above. Further, the vertically extending portion 63B is a portion extending in the up and down direction (Z direction). For this reason, the position of the height direction (Z direction) differs between the insertion piece part 61B and the binding part 62B.

  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 dimension in the width direction (Y direction) larger than that of the insertion piece portion 61B. Although both ends of the chip support piece 64B enter the resin portion of the bobbin body 30A, the portion between both ends is exposed to the opening 35B1. One side of the chip-like capacitor 100B is attached to the chip support piece 64B in a state where it is electrically connected.

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

  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 obtain such a configuration, the bottom wall 35B3 of the terminal mounting portion 35B is provided thicker than the bottom surface 32B3. And in this bottom wall 35B3, a part of connection terminal 60B1-60B3 mentioned above is the state embedded, for example by forming by insert molding.

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

  Further, unlike the connector connection portion 40A in the first embodiment, the connector connection portion 40B is provided along the longitudinal direction (X direction). And the collar part 43B is provided in the part which divides the terminal attachment part 35B and the connector connection part 40B. In this embodiment, the flange portion 43B is provided in a rectangular plate shape, and a step portion 44B is provided on the outer peripheral edge portion of the flange portion 43B. The step 44B is configured to fit the opening edge of the case 90A.

  The antenna device 10B of the present embodiment also includes a coil 50B similar to the above-described coil 50A. That is, the conducting wire 51B forming the coil 50B has a smaller diameter than the conducting wire used in the conventional antenna device. Specifically, in the conventional antenna device, when the diameter of 0.26 mm is an appropriate conductor diameter, the conductor 51B is significantly smaller in size than the appropriate diameter, and the diameter is 0.08 mm. There is something to do. Thereby, in the antenna device 10B, it is possible to lower the Q value without mounting a resistance element.

  The antenna device 10B of the present embodiment also includes a copper tape winding part 70B similar to the copper tape winding part 70A. In the antenna device 10B, when the temperature rises, the Q value changes as shown in FIG. As a result, even if a temperature change occurs, it is possible to suppress variations in the Q value.

<About effect>
Also with respect to the antenna device 10B according to the present embodiment, the same effects as those of the antenna device 10A according to the first embodiment described above can be exhibited.

  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. For this reason, inside the core insertion part 34B, it can be slid to the terminal attachment part 35B side. Therefore, in addition to the adjustment of the inductance value by sliding the first layer (upper layer) conducting wire 51B in the sparse winding part 54B, the inductance value can be increased or decreased by sliding the core 20B, or the Q value (adjusted Q value). ) Can be adjusted.

(Third embodiment)
Hereinafter, an antenna device 10C according to a third embodiment of the present invention will be described with reference to the drawings. In the present embodiment, the description of the configuration common to the antenna device 10A in the first embodiment described above is omitted, but the alphabet related to the first embodiment is added at the end of the reference numeral. An alphabet “C” is attached instead of “A”. Note that the alphabet “C” has a configuration related to the third embodiment. Therefore, although not described and illustrated in the third embodiment, the same configuration as that of the antenna device 10A in the first embodiment may be described with an alphabet “C”.

  FIG. 12 is a side sectional view showing an antenna apparatus 10C according to the third embodiment of the present invention. The antenna device 10C of the present embodiment also includes a coil 50C similar to the coil 50A described above. That is, the conducting wire 51C forming the coil 50C has a smaller diameter than the conducting wire used in the conventional antenna device. Specifically, in the conventional antenna device, when the diameter of 0.26 mm is an appropriate conductor diameter, the conductor 51C is significantly smaller in size than the appropriate diameter, and the diameter is 0.08 mm. There is something to do. Thereby, in the antenna device 10C, it is possible to reduce the Q value without mounting a resistance element.

  Further, the antenna device 10C according to the present embodiment does not include the copper tape winding portion 70A according to the first embodiment described above. However, when the antenna device 10C is attached to an attachment part 110C such as a metal vehicle body, for example, an eddy current is generated in the metal of the attachment part 110C, so that the same effect as the copper tape winding part 70A described above is obtained. It is possible to demonstrate the effect.

  Specifically, as shown in FIG. 12, the case 90C is provided with an interval maintaining portion 91C. The interval maintaining part 91C is set to a distance such that the distance from the core 20C to the attachment surface 37C of the bobbin body 30C has a desired Q value. Specifically, in the antenna device in which the distance maintaining portion 91C having a prescribed dimension is present although the diameter of the conducting wire 51C is the same as the conventional one, when a temperature change occurs, the two-dot chain line in FIG. Fluctuation of the Q value occurs. On the other hand, in the antenna device in which the coil 50C is formed by the conductive wire 51C having a small diameter but the interval maintaining portion 91C is not present, the Q value varies as indicated by the alternate long and short dash line in FIG.

  On the other hand, in the antenna device 10C of the present embodiment, the Q value changes in a state where the Q values indicating the temperature changes indicated by the one-dot chain line and the two-dot chain line in FIG. Therefore, the variation in the Q value can be made smaller than that in the conventional configuration.

  In addition, the dimension of the space | interval maintenance part 91C can be suitably set, for example so that it may be settled in the predetermined fluctuation range in the practical temperature range mentioned above. As an example thereof, setting the dimension of the interval maintaining portion 91C to 13.1 mm can be mentioned.

  Here, in the antenna device 10 </ b> C of the third embodiment, the conductor 51 </ b> C may have the same size (that is, an appropriate diameter) as the conventional one, and only the interval maintaining unit 91 </ b> C may exist. When such a configuration is adopted, the antenna device 10C secures an inductance value L that is equal to or higher than that of the conventional antenna device, and a Q value that represents the sharpness of the resonance peak is applied to the system in which the antenna device 10C is incorporated. It can be lowered together. Such adjustment that lowers the Q value is realized by mounting a resistive element in the conventional configuration as disclosed in Patent Document 1, but in this embodiment, the resistive element is mounted. The Q value can be lowered without doing so.

<About effect>
The antenna device 10C according to the present embodiment includes an interval maintaining portion 91C that defines an interval between a core 20C and a mounting portion 110C such as a metal vehicle body corresponding to an eddy current generating means that generates eddy current. . In the case where the coil is provided while the metal attachment portion 110C does not exist, the Q value (first Q value) representing the sharpness of the resonance peak by the coil 50C is based on the temperature change of the resistance value of the conducting wire 51C. It decreases with increasing temperature. Further, in the case where the metal attachment portion 110C exists, the Q value (second Q value) representing the sharpness of the resonance peak due to the metal attachment portion 110C is a temperature change of the resistance value of the metal attachment portion 110C. It increases with temperature rise due to current fluctuation corresponding to. The rate of increase / decrease in the temperature rise of the Q value (adjustment Q value) representing the sharpness of the resonance peak based on the coil 50C and the metal mounting portion 110C is the rate of increase / decrease in the temperature rise of the first Q value and the second Q value. It is provided to be smaller than the rate of increase / decrease in the temperature rise.

  For this reason, it is possible for the antenna device 10 </ b> C to suppress a variation in the Q value (adjusted Q value) due to a temperature change, even though the configuration is simpler. In particular, since the variation of the Q value can be suppressed in an environment where the temperature change is likely to occur, such as in-vehicle use, the performance of the antenna device 10C can be stabilized.

<Modification>
As mentioned above, although each embodiment of this invention was described, this invention can be variously deformed besides this. This will be described below.

  In the first and second embodiments described above, as the eddy current generating means and the winding part, the copper tape winding part 70A around which the copper tape is wound is described. However, the eddy current generating means and the winding portion are not limited to the copper tape winding portion 70A, and various types can be applied as long as a film-like member including a nonmagnetic metal layer is wound. . For example, various materials such as a film-shaped steel plate and an aluminum foil can be used.

  In the third embodiment described above, the interval maintaining unit 91C is provided integrally with the case 90C. However, the interval maintaining unit 91C may have a separate configuration from the case 90C. For example, the bobbin body and the case may have a common configuration in each antenna device, and a fitting body having a fitting structure that fits the bobbin body and the case may be sandwiched between the bobbin body and the case. In the case of such a configuration, it is possible to adjust the distance between the core 20C (coil 50C) and the metal attachment portion 110C only by changing the fitting body.

  Moreover, in each above-mentioned embodiment, the copper tape is demonstrated as a film-form member. However, the film-like member is not limited to such a narrow tape-like member, and includes a wide sheet-like member.

  Further, in the third embodiment described above, a configuration including an eddy current generating means and a winding part such as a copper tape winding part may be adopted in addition to the interval maintaining part 91C.

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

  In 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 in the longitudinal direction (X direction). It is good also as a structure located in the other side (X2 side).

  Alternatively, 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 positioned between the sparse winding portions 54A and 54B. Further, a configuration may be adopted in which a plurality of densely wound portions 53A and 53B are provided and the loosely wound portions 54A and 54B are positioned between the densely wound portions 53A and 53B.

  Further, in each of the above-described embodiments, a case where only one core 20A, 20B exists is described. However, a plurality of cores may exist. In addition, the bobbin body may have any configuration as long as a densely wound portion and a sparsely wound 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 to 10C ... Antenna device, 20A to 20C ... Core, 30A to 30C ... Bobbin body, 31A, 31B ... Bobbin part, 32A, 32B ... Winding frame part, 32A1, 32B1 ... Side wall part, 32A2, 32B2 ... Top face, 32A3 32B3 ... bottom surface, 32A4, 32B4 ... punched portion, 32A5, 32B5 ... slit, 32A6, 32B6 ... core holding projection, 33A, 33B ... partitioning part, 34A, 34B ... core insertion part, 35A, 35B ... terminal attachment part, 35A1 , 35B1 ... opening, 35A2 ... partition wall, 35B3 ... bottom wall, 37C ... mounting surface, 40A, 40B ... connector connection part, 41A ... partition wall part, 42A ... terminal hole, 43B ... collar part, 44B ... step part, 50A , 50B ... coil, 51A, 51B ... conducting wire, 53A, 53B ... dense winding part, 54A, 54B ... sparse winding part, 60A, 60 1, 60A2, 60B, 60B1, 60B2, 60B3 ... connection terminal, 61A, 61B ... plug piece, 62A, 62B ... binding part, 63B ... vertical extension part, 64B ... chip support piece part, 70A, 70B ... copper Tape winding part (corresponding to eddy current generating means and winding part), 90A to 90C ... case, 91C ... interval maintaining part, 100B ... capacitor, 110C ... metal mounting part 110C, S1 ... gap

Claims (8)

A core formed of a magnetic material;
A coil formed by winding a conducting wire around the outer periphery of the core;
Flat plate eddy current generating means disposed on the outer peripheral side of the core and the coil;
With
In the case where the coil is provided while the eddy current generating means is not present, the Q value (referred to as the first Q value) representing the sharpness of the resonance peak due to the coil is based on the temperature change of the resistance value of the conducting wire. Decrease with increasing temperature,
In the case where the eddy current generating means is provided, the Q value (the second Q value) indicating the sharpness of the resonance peak by the eddy current generating means corresponds to the temperature change of the resistance value of the eddy current generating means. Increase with temperature rise due to current fluctuation,
The increase / decrease rate in the temperature rise of the Q value (adjusted Q value) representing the sharpness of the resonance peak based on the coil and the eddy current generating means is the increase / decrease rate in the temperature rise of the first Q value and the second Q value. It is provided to be smaller than the rate of change in temperature rise,
An antenna device characterized by that. The antenna device according to claim 1,
The eddy current generating means is a winding part formed by winding a film-like member having a nonmagnetic metal layer.
An antenna device characterized by that. The antenna device according to claim 2, wherein
The sheet-like member is a copper tape provided with a copper foil layer, and the winding part is a copper tape winding part formed by winding the copper tape.
An antenna device characterized by that. The antenna device according to claim 2 or 3, wherein
The winding portion is located at a portion near both ends in the longitudinal direction of the core,
An antenna device characterized by that. The antenna device according to any one of claims 1 to 4, wherein
Compared with a case where a resistance element is connected in series to a series resonance circuit including the coil, the conductive wire constituting the coil has a diameter reduced so as to have at least a part of the resistance value of the resistance element. Being
An antenna device characterized by that. The antenna device according to any one of claims 1 to 5,
The conductor has a diameter of 0.1 mm or less,
An antenna device characterized by that. A core formed of a magnetic material;
A coil formed by winding a conducting wire around the outer periphery of the core;
An interval maintaining unit for defining an interval between the core and the eddy current generating means disposed on the outer peripheral side of the coil;
With
In the case where the coil is provided while the eddy current generating means is not present, the Q value (referred to as the first Q value) representing the sharpness of the resonance peak due to the coil is based on the temperature change of the resistance value of the conducting wire. Decrease with increasing temperature,
In the case where the eddy current generating means is present, the Q value (the second Q value) representing the sharpness of the resonance peak by the eddy current generating means corresponds to the temperature change of the resistance value of the eddy current generating means. Increase with temperature rise due to current fluctuation,
The increase / decrease rate in the temperature rise of the Q value (adjusted Q value) representing the sharpness of the resonance peak based on the coil and the eddy current generating means is the increase / decrease rate in the temperature rise of the first Q value and the second Q value. It is provided to be smaller than the rate of change in temperature rise,
An antenna device characterized by that. A core insertion step of inserting a core formed of a magnetic material into the core insertion portion of the bobbin body having a partition portion in the middle in the longitudinal direction;
A coil forming step of forming a coil by winding a conductive wire around the bobbin body;
A winding part forming step of forming a winding part by winding a film-like member having a nonmagnetic metal layer on the outer peripheral side of the core;
Have
In the case where the coil is provided while the winding portion does not exist, the Q value (the first Q value) indicating the sharpness of the resonance peak due to the coil is based on the temperature change of the resistance value of the conducting wire. Decreases with increasing temperature,
In the case where the winding part is provided, the Q value (the second Q value) representing the sharpness of the resonance peak by the winding part is determined by current fluctuation corresponding to the temperature change of the resistance value of the winding part. Increases with increasing temperature,
The rate of increase / decrease in the temperature increase of the Q value (adjusted Q value) representing the sharpness of the resonance peak based on the coil and the winding portion is the rate of increase / decrease in the temperature increase of the first Q value and the temperature of the second Q value. The winding portion is formed so as to be smaller than the increase / decrease rate in the rise,
A method for manufacturing an antenna device.

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