JP2016218748A - Communication terminal and communication terminal manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a band-shaped communication terminal to efficiently secure stable communication.SOLUTION: An opening of a storage unit (10) storing an antenna board (23) and an IC card (21) pasted with a double-sided tape (22) provided with a hole (221) at a position corresponding to a capacitor (231) is sealed with a lid (30) provided with a recess (301) at a position corresponding to the capacitor.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a band-type communication terminal mounted with an electronic substrate.

  Conventionally, a band-type communication terminal worn on a person's arm or the like is known. For example, Patent Document 1 discloses a wristband in which an inlet sealing body formed by sealing both sides of an inlet having an antenna and an IC chip mounted on a PET film with a PEN film.

JP 2008-293394 A (published December 4, 2008)

  However, the conventional technology as described above has the following two problems. First, an electronic board including an IC chip or the like stored in the belt portion of the band may be damaged by bending or stretching of the belt portion, and it is difficult to efficiently ensure stable communication. There is a problem. Secondly, since the antenna and the like necessary for securing the communicable distance of the communication terminal are stored in the belt portion, the area for the antenna and the like is limited, and the communication function of the antenna and the like is limited. Since it is difficult to confirm, the communication terminal has a problem that it is difficult to efficiently secure stable communication.

  The present invention has been made in view of the above two problems, and an object of the present invention is to provide a communication terminal capable of efficiently ensuring stable communication for a band-type communication terminal, and manufacture of the communication terminal. To realize the method.

  In order to solve the above problems, a communication terminal according to one embodiment of the present invention is a band-type communication terminal, which is provided in a belt and has an opening, and an electronic board stored in the storage And a substantially plate-like lid that closes the opening in a state of being placed on the electronic substrate body on the opening side of the electronic substrate body, and the electronic substrate body includes capacitors and resistors. An antenna substrate including at least one; an IC card including an IC chip; and a double-sided tape for bonding the antenna substrate and the IC card, wherein the double-sided tape includes the capacitor, the resistor, and the IC chip. There is a hole at a position corresponding to at least one, and the lid body has a surface on the surface facing the electronic substrate body with the antenna substrate on the opening side, the capacitor, the resistor, And it has a recess at a position corresponding to at least one of the IC chip.

  In order to solve the above problems, a communication terminal according to one embodiment of the present invention is a band-type communication terminal, includes two sub-capacitors connected in parallel, and has a communicable distance. An antenna substrate having an antenna circuit in which a resonance frequency is set to be equal to or greater than a predetermined distance is provided, and each of the two sub-capacitors has a resonance frequency of the antenna circuit when only one of them is provided. It has a capacitance set to be less than the distance.

  In order to solve the above problem, a method for manufacturing a communication terminal according to one aspect of the present invention is a method for manufacturing a band-type communication terminal, which includes an antenna substrate including at least one of a capacitor and a resistor, A step of forming an electronic substrate body by bonding an IC card including an IC chip with a double-sided tape having a hole at a position corresponding to at least one of the capacitor, the resistor, and the IC chip. And storing the electronic substrate body formed in the forming step in a storage portion provided on the belt of the band and having an opening in a state where the antenna substrate is on the opening side, and the storing step. A substantially plate-like lid body having a recess on a surface facing the electronic substrate body, the recess being formed on the capacitor. Said resistor, and arranged so as to correspond to at least one of said IC chip, and a closure step of closing the opening.

  In order to solve the above problem, a method for manufacturing a communication terminal according to one aspect of the present invention is a method for manufacturing a band-type communication terminal, which includes two sub-capacitors connected in parallel electrically. Including an antenna substrate forming step for forming an antenna substrate provided with an antenna circuit in which a resonance frequency is set so that a communicable distance is equal to or greater than a predetermined distance, and each of the two sub-capacitors includes only one of them. When provided, the antenna circuit has a capacitance set such that the resonance frequency of the antenna circuit is less than the predetermined distance.

  According to one embodiment of the present invention, there is an effect that stable communication can be efficiently ensured for a band-type communication terminal.

It is a disassembled perspective view which shows the structure of the storage part of the band which concerns on Embodiment 1 of this invention. It is a perspective view which shows the structure of the whole band containing the storage part of FIG. It is the decomposition | disassembly top view and decomposition | disassembly sectional drawing which show the structure of the accommodating part of the band of FIG. It is sectional drawing which shows the structure of the storage part of a band of FIG. 1, and an IC card. It is sectional drawing explaining the size of each member in the storage part of the band of FIG. It is sectional drawing which shows the detailed structure of the accommodating part of the band of FIG. It is the decomposition | disassembly top view and decomposition | disassembly sectional drawing which show the structure of the storage part of the band which concerns on Embodiment 2 of this invention. It is sectional drawing which shows the structure of the storage part of the band of FIG. It is the figure and circuit diagram which show the outline | summary of the antenna substrate of the band which concerns on Embodiment 3 of this invention. It is a figure which shows the detail of the antenna board | substrate of FIG. It is a figure which shows the relationship between the resonant frequency of this antenna circuit, and the communicable distance about the antenna circuit formed in the antenna board | substrate of FIG.

Embodiment 1
Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 6. Here, an example will be described in which the band-type communication terminal according to one embodiment of the present invention is realized as the wristband-type communication terminal 100 (hereinafter, abbreviated as the band 100). In the following description, the band 100 will be described using an example of a wristband type communication terminal. However, the band 100 according to the present invention is not limited to the wristband type, and may be a band-type communication terminal that is attached to other parts of the human body such as arms and legs, or to a rod-like part other than the human body. .

(Device overview)
FIG. 1 is an exploded perspective view showing the structure of the storage unit 10 of the band 100. In order to facilitate understanding of the band 100, the outline of the band 100 will be described as follows. That is, as shown in FIG. 1, the band 100 is a band-type communication terminal, which is provided on a belt and has a storage unit 10 having an opening, an electronic substrate body 20 stored in the storage unit 10, and an electronic substrate A substantially plate-like lid body 30 that closes the opening in a state of being placed on the electronic substrate body 20 on the opening side of the body 20, and the electronic substrate body 20 includes at least one of a capacitor 231 and a resistor. Including the antenna substrate 23, the IC card 21 including the IC chip 211, and the double-sided tape 22 that bonds the antenna substrate 23 and the IC card 21. The double-sided tape 22 includes the capacitor 231, the resistor, and the IC chip 211. Has a hole 221 at a position corresponding to at least one of the above, and the lid 30 is a surface of the surface facing the electronic substrate 20 with the antenna substrate 23 on the opening side. Capacitor 231, has the resistor, and the recess 301 at positions corresponding to at least one IC chip 211.

  According to the above configuration, at least one of the hole 221 and the recess 301 is provided around at least one of the capacitor 231, the resistor, and the IC chip 211, that is, a gap is provided. Due to the gap, the capacitor 231 stored in the storage unit 10 provided in the belt of the band 100, the resistor, and the IC chip 211 can be physically There is no direct load. Therefore, the electronic substrate body 20 including the capacitor 231 and at least one of the resistors and the IC chip 211 is not likely to be damaged by bending or stretching of the belt, and stable communication with the band 100 is efficiently performed. Can be secured.

  The thickness of the IC card 21 of the band 100 is 0.5 mm.

  According to the above configuration, since the thickness of the IC card 21 is thinner than the thickness of a conventional normal IC card (for example, 0.8 mm), when the IC card 21 is bent, the IC chip 211 is formed. The applied force (stress) can be suppressed. Therefore, when the IC card 21 is bent, the possibility that the IC chip 211 is peeled off from the IC card 21 and is damaged can be suppressed, and stable communication can be efficiently secured for the band 100.

  In the band 100, the IC chip 211 may be disposed so as not to overlap the capacitor 231 and the resistor.

  According to the above configuration, the IC chip 211 is arranged so as not to overlap the capacitor 231 and the resistor. Therefore, even if the belt is bent and stretched, the IC chip 211 is not connected to the capacitor 231. And there is no contact with the resistor. Therefore, at least one of the capacitor 231 and the resistor and the IC chip 211 do not collide with each other and are damaged even by bending or stretching of the belt, and stable communication with the band 100 is efficiently performed. Can be secured.

  In FIG. 1, the nameplate pasting area 37 is an area provided on the uppermost surface of the lid 30 (the surface of the lid 30 on the side contacting the wrist of the user wearing the band 100). Attached. The nameplate 50 is, for example, a seal on which a “FeliCa (registered trademark)” logo and notes relating to the use of the band 100 are described. Next, the overall outline of the band 100 whose outline has been described above will be described with reference to FIG.

(Overview of the entire band)
FIG. 2 is a perspective view showing the entire structure of the band 100 including the storage unit 10. As shown in FIG. 2, the annular belt of the band 100 includes a portion where the storage portion 10 is provided and a mounting portion 60 which is a portion where the storage portion 10 is not provided. The storage unit 10 is a recess formed in the belt. The belt can be molded with the same material as that of the mounting portion 60 so that a design with a sense of unity between the storage portion 10 and the mounting portion 60 can be realized.

  The lid 30 is a substantially plate-like heat insulating plate that closes the opening of the storage unit 10 in which the electronic substrate body 20 is stored. As will be described later with reference to FIG. 3, the lid 30 has a notch 31 having a standing surface that is erected toward the outside of the opening at the periphery of the opening-side surface of the storage unit 10. Is provided.

  The fixing member 40 fixes the electronic substrate body 20 and the lid body 30 stored in the storage unit 10 to the inside of the storage unit 10. More precisely, the melted fixing member 40 is poured (filled) between the cutout portion 31 of the lid 30 and the inner wall of the storage unit 10 and is integrated with the belt on which the storage unit 10 is provided. And then cured.

  Next, the storage unit 10, the electronic substrate body 20 and the lid body 30 stored in the storage unit 10 will be described in detail with reference to FIGS. 3 and 4.

(Details of electronic substrate and lid)
FIG. 3 is an exploded top view and an exploded sectional view showing the structure of the storage unit 10 of the band 100. FIG. 3A is an exploded top view showing the structure of the storage unit 10 of the band 100. FIG. 3B is an exploded cross-sectional view of the storage unit 10 in the short direction, showing the structure of the storage unit 10 of the band 100. FIG. 3C is an exploded cross-sectional view in the longitudinal direction of the storage unit 10 showing the structure of the storage unit 10 of the band 100.

  FIG. 4 is a cross-sectional view showing the structure of the storage unit 10 and the IC card 21 of the band 100. 4A is a virtual cross-sectional view for explaining the arrangement position of each member in the thickness direction of the band 100 with respect to the structure of the storage unit 10 of the band 100, and FIG. It is a virtual sectional view. In FIG. 4A, the IC chip 211 and the capacitor 231 are shown side by side, but actually, in the storage unit 10, the IC chip 211 and the capacitor 231 are aligned in the thickness direction of the band 100. It is not necessarily arranged in. 4B is a longitudinal sectional view of the storage unit 10 showing the structure of the storage unit 10 of the band 100. FIG. FIG. 4C is a longitudinal sectional view of the IC card 21 showing the structure of the IC card 21.

  As shown in FIGS. 3 and 4, the storage unit 10 of the band 100 stores a substantially plate-shaped electronic substrate body 20 including an IC card 21 bonded with a double-sided tape 22 and an antenna substrate 23 (resonant coil). Has been. The opening of the storage unit 10 storing the electronic substrate body 20 is closed by the lid body 30.

  The storage unit 10 is provided on the belt of the annular band 100. Specifically, the opening of the storage unit 10 is provided on the back surface of the band 100 (the surface that contacts a person, specifically, the surface that touches the wrist), and the storage unit 10 has a depth of the storage unit 10. The direction is formed so as to coincide with the thickness direction from the back surface to the front surface of the band 100. That is, the storage unit 10 is provided in a concave shape on the back surface of the belt of the band 100.

  The electronic substrate body 20 is a substantially plate-like laminate in which an IC card 21 and an antenna substrate 23 are bonded together with a double-sided tape 22, and is stored in the storage unit 10. The electronic substrate body 20 and the bottom surface of the storage unit 10 may be bonded to each other with a double-sided tape (not shown) to fix the electronic substrate body 20 to the bottom of the storage unit 10. That is, the IC card 21 and the bottom of the storage unit 10 may be bonded with a double-sided tape (not shown).

  The band 100 may be stored in the storage unit 10 in a state where the belt of the band 100 has an annular shape and the electronic substrate body 20 is curved in accordance with the shape of the belt. That is, the electronic substrate body 20 may be stored in the storage unit 10 in a state where the electronic substrate body 20 is bent in accordance with the shape (substantially annular) of the band 100 by the following method. That is, the storage unit 10 is mounted by a double-sided tape (not shown) pasted on the surface of the IC card 21 that faces the bottom surface of the storage unit 10 in a state in which the electronic substrate body 20 is bent in accordance with the shape of the belt of the band 100. It may be fixed to the bottom surface of. Since the electronic substrate body 20 is stored in the storage unit 10 in a state of being curved according to the shape of the belt, the function (for example, the electronic substrate body 20) is included in the belt of the band 100 having a curved design. The function of the FeliCa chip) can be mounted.

  The IC card 21 is, for example, a plastic card including a copper winding, and includes an IC chip 211. The IC chip 211 is a non-contact IC chip such as a FeliCa chip, for example. The IC card 21 is a plastic card with a thickness of 0.5 mm, which is thinner than the thickness of a conventional general IC card (usually 0.8 mm), and has a substantially rectangular shape with a short side of 17 mm and a long side of 49 mm. It is.

  The double-sided tape 22 only needs to be disposed between the IC card 21 and the antenna substrate 23 so that they can be bonded together, and a general double-sided tape can be used. The thickness of the double-sided tape 22 is 0.3 mm, which is the same as the thickness of a capacitor 231 described later. A hole 221 is provided at a position of the double-sided tape 22 corresponding to the capacitor 231 provided in the antenna substrate 23. The IC card 21 and the antenna substrate 23 are attached to each other by a double-sided tape 22 in which a hole 221 is provided at a position corresponding to the capacitor 231.

  The antenna substrate 23 is a flexible printed circuit (hereinafter abbreviated as “FPC”) in which a coil (booster coil) is formed with a copper pattern, and includes a capacitor 231 that is a small chip capacitor. In the antenna substrate 23, the FPC pattern forms a coil, and a capacitor 231 is connected to the coil to form a resonance circuit. That is, the antenna substrate 23 has the resonance frequency of the antenna substrate 23 set to a desired value by mounting the capacitor 231 on the coil (inductance L) formed by the FPC pattern. 1 and the like show the capacitor 231 as a single capacitor, the capacitor 231 may be a synthetic capacitor formed by electrically connecting two sub-capacitors in parallel, for example. Will be described later with reference to FIG.

  The lid 30 is a substantially plate-like heat insulating plate, and stands upright at the peripheral edge of the opening-side surface of the storage portion 10 toward the outside of the opening (upper side of the paper surface in FIG. 3B). A notch 31 having a mounting surface is provided. That is, at the peripheral portion of the surface of the lid 30 on the opening side of the storage portion 10, a standing surface that stands up toward the outside of the opening and a lateral surface that intersects (orthogonally) the standing surface The notch part 31 which has is provided. The lowermost surface of the lid 30 is a surface that is in contact with (opposes to) the electronic substrate body 20 (specifically, the antenna substrate 23), and a recess 301 is provided at a position corresponding to the capacitor 231 of the antenna substrate 23. .

  As shown in FIGS. 3B and 3C, the storage unit 10 of the band 100 is in contact with the back side of the belt (the wrist of the user wearing the band 100 in the short direction and the long direction of the belt 100). In a cross-sectional view cut from the side) to the front side, a lid 30 having a convex (inverted T-shaped) cross section is provided. That is, the lid 30 is provided with a notch 31 having a standing surface that stands up toward the outside of the opening at the peripheral edge of the opening-side surface of the storage unit 10. Then, a molten resin is filled between the notch portion 31 and the inner wall of the storage portion 10, and the fixing member 40 is formed by curing the resin.

  The fixing member 40 fixes the electronic substrate body 20 and the lid body 30 stored in the storage unit 10 to the inside of the storage unit 10. More precisely, the melted fixing member 40 is poured (filled) between the notch 31 and the inner wall of the storage unit 10, and is integrated with the belt provided with the storage unit 10, and then cured. Is done. The fixing member 40 that is poured into the cutout portion 31 and cured after being integrated with the belt provided with the storage portion 10 fixes the electronic substrate body 20 and the lid body 30 to the inside of the storage portion 10. Can do. That is, the melted fixing member 40 is poured into the cutout portion 31 of the lid 30 stored in the storage unit 10 so as to overlap the electronic substrate body 20, and then cured, thereby being cured. A fixing member 40 that fixes the substrate body 20 and the lid body 30 to the inside of the storage unit 10 is formed. The melted fixing member 40 is poured into the notch 31 (filled) and then cured, so that it is integrally formed with the belt on which the storage 10 is provided (that is, the inner wall of the storage 10). It becomes.

(Material and size of each member)
FIG. 5 is a cross-sectional view illustrating the size of each member in the storage unit 10 of the band 100. Hereinafter, with reference to FIG. 5, desirable materials, sizes, and the like for each member constituting the band 100 will be described. First, desirable materials for each member will be described.

  As described above, the storage unit 10 is provided in the belt of the band 100, and the belt includes the mounting unit 60. The material used for the belt is desirably thermoplastic polyurethane (hereinafter abbreviated as “TPU”) or silicon rubber. The storage unit 10 is stored in the storage unit 10 by forming the storage unit 10 using a hard material such as high-hardness TPU, high-hardness silicon rubber, or polycarbonate (PolyCarbonate, hereinafter abbreviated as “PC”). Damage to the IC chip 211 and the capacitor 231 can be prevented.

  As a material used for the fixing member 40, TPU or silicon rubber is desirable. In addition, the following effects are acquired by making the material used for the fixing member 40 and the storage part 10 the same as the material used for the mounting part 60. That is, since the joint between the fixing member 40 and the storage unit 10 and the joint between the storage unit 10 and the mounting unit 60 can be eliminated, an effect that the mounting unit 60 and the storage unit 10 can be integrated is formed. Get. Moreover, the product excellent in the unity feeling of the junction part of the storage part 10 and the fixing member 40 can also be manufactured by making the material of the storage part 10 into PC and making the material of the fixing member 40 into TPU.

  As a material used for the lid 30, TPU, silicon rubber, or polycarbonate can be used. Since TPU or silicon rubber has rubber-like elasticity, the physical load applied to the storage unit 10 is dispersed by using TPU or silicon rubber for the lid 30, thereby preventing the electronic substrate body 20 from being damaged. It becomes possible.

  As shown in FIG. 2, the band 100 exposes the lid 30 on the back surface of the band 100 (the surface in contact with the wrist of the user wearing the band 100). Then, by using a material (for example, PC) having a higher hardness than the TPU (or silicon rubber) used for the belt portion of the band 100 and the fixing member 40 for the lid body 30, the following processing is performed on the lid body 30. This can be performed more easily. That is, when the cover 30 is exposed on the back surface of the band 100, that is, when the top surface of the cover 30 is exposed on the back surface of the band 100, the top surface is engraved, printed, and nameplate. It is possible to more easily attach 50 (seal) or the like.

  Further, the lid 30 having sufficient thickness and mechanical strength is placed on the electronic substrate body 20 and stored in the storage unit 10 to prevent the force applied to the storage unit 10 from being transmitted to the electronic substrate body 20. That is, resistance to force can be improved.

  The band 100 is a state in which the electronic substrate body 20 is stored in the storage unit 10 and is bent in the storage unit 10 in a state in which the electronic substrate body 20 is bent in accordance with the belt shape (substantially annular) of the band 100. The lid body 30 is disposed so as to overlap the electronic substrate body 20 stored in the above. Thereafter, molten resin (molten fixing member 40) is poured (filled) into the cutout portion 31 of the lid 30 and the molten fixing member 40 is cured to match the shape of the belt of the band 100. The electronic substrate body 20 and the lid body 30 stored in the storage unit 10 in a bent state are fixed to the inside of the storage unit 10 by the fixing member 40.

  Therefore, the function of the electronic substrate body 20, that is, the function of, for example, a FeliCa card can be mounted in the belt of the band 100 having a curved design.

  Next, a desirable size of each member constituting the band 100 formed of the material described above will be described. As shown in FIG. 5, the thickness T21 of the IC card 21 is 0.5 mm, which is smaller than the thickness (usually 0.8 mm) of a conventional general IC card (eg, FeliCa card). Moreover, the thickness T22 of the double-sided tape 22 is 0.3 mm, and the thickness T231 of the capacitor 231 provided in the antenna substrate 23 is also 0.3 mm. Accordingly, as shown in FIG. 5, the capacitor 231 does not protrude through the hole 221 provided in the double-sided tape 22 to the side of the double-sided tape 22 that is in contact with the IC card 21. Furthermore, the thickness T23 of the antenna substrate 23 is 0.2 mm, and the depth of the concave portion 301 provided on the lowermost surface of the lid 30 (the surface in contact with (opposite with) the electronic substrate body 20, particularly the antenna substrate 23). D301 is 0.9 mm.

(Use of conventional production line)
The size of a conventional general IC card such as a so-called FeliCa card has been standardized, and is, for example, a substantially rectangular shape with a short side of 53.89 mm and a long side of 85.6 mm. Here, in the conventional general IC card, an antenna provided in the IC card (an antenna for the IC card to communicate) extends over the entire surface of the IC card, and an area required for the antenna. Is secured. Further, an IC card manufacturing method has been established by optimizing the size of the conventional general IC card, and an attempt is made to manufacture an IC card having a size different from that of the conventional general IC card. In this case, the manufacturing cost increases. Further, since IC cards such as FeliCa cards can be equipped with a plurality of services such as electronic money and employee ID cards, security management is necessary, and IC card ticketing apparatus having a size different from that of the conventional IC card is used. Cannot be added easily.

  A band 100 which is a band-type communication terminal includes an electronic board body (in particular, an IC for a communication function of the band 100) in a storage unit 10 provided on a curved belt and having a width (short direction) of 20 mm. Card). However, the conventional general IC card cannot be stored in the storage unit 10 in the same size. Accordingly, the inventor of the present invention (hereinafter referred to as “the inventor of the present application”) uses the following device to make the band 100 while using the IC card manufactured by the conventional general IC card manufacturing line. Succeeded in securing the communication function.

  First, the inventor of the present application has a size (for example, short side :) that can store the IC card in the storage unit 10 after the ticket issuing process of the IC card manufactured by the conventional general IC card manufacturing line. 17 mm, long side: 49 mm), and the IC card 21 was formed. The IC card 21 is manufactured as a card of the above-described conventional general IC card (short side: 53.89 mm, long side: 85.6 mm), and then cut into a size that can be stored in the storage unit 10. You can enjoy the benefits. That is, the IC card 21 can be manufactured using an existing IC card ticketing apparatus (for example, an existing FeliCa card manufacturing line) as it is.

  Second, since the IC card 21 cannot secure a sufficient antenna area with the above-mentioned size, the inventor of the present application stores the resonance coil in the storage unit 10 in combination with the IC card 21, so that the communication function of the band 100 ( In particular, a communicable distance) was secured. Specifically, the antenna substrate 23, which is an external coil for resonance in which a capacitor 231 (chip capacitor) is combined with the FPC, is stored in the storage unit 10 in combination with the IC card 21. In the antenna substrate 23, a resonance circuit is configured in which a capacitor 231 is connected to a coil (inductance L) formed by an FPC pattern, and the resonance of the antenna substrate 23 is selected by selecting the capacitance of the capacitor 231. The frequency is set to a desired value. That is, by setting the capacitance of the capacitor 231 to a desired value, it is possible to adjust the resonance frequency of the antenna substrate 23 and obtain sufficient resonance.

  The inventor of this application desires for the band 100 by combining the IC card 21 having a relatively high resonance frequency with the resonance circuit (booster coil) of the antenna substrate 23 having a relatively low resonance frequency. The communication frequency of the band 100 was ensured. That is, the resonant frequency of each of the IC card 21 and the antenna substrate 23 (resonant coil) is higher than the modulation frequency of the communication standard, and the communicable distance of the band 100 is increased by combining the IC card 21 and the antenna substrate 23. ing. The resonance frequency of the antenna substrate 23 is set to be a resonance frequency close to a communication frequency that can secure a desired communicable distance for the band 100.

  These frequencies hold the following relationship: That is, the resonance frequency of the IC card 21 is higher than the resonance frequency of the antenna substrate 23, and the resonance frequency of the antenna substrate 23 is higher than the resonance frequency of the combination of the IC card 21 and the antenna substrate 23. The resonance frequency that is combined with is substantially the same as the modulation frequency of the communication standard. That is, the relationship “(resonance frequency of the IC card 21)> (resonance frequency of the antenna substrate 23)> (resonance frequency combining the IC card 21 and the antenna substrate 23) ≈ (modulation frequency of the communication standard)” is established. .

  Here, when the capacitor 231 is to be formed on the IC card 21, it is necessary to perform various adjustments by trimming the IC card 21 or making a prototype of the IC card 21 including the capacitor 231.

  On the other hand, the band 100 includes the antenna substrate 23 for securing the communicable distance of the band 100 separately from the IC card 21, and it is not necessary to mount the capacitor 231 on the IC card 21. In addition, since the band 100 includes the antenna substrate 23 for securing the communicable distance of the band 100 separately from the IC card 21, the band 100 can improve the degree of freedom in designing the band 100. It is possible. Further, the band 100 can adjust the resonance frequency of the antenna substrate 23 by selecting only the capacitance of the capacitor 231. Further, the combination of the FPC and the chip capacitor is a combination of parts widely used in so-called electronic devices, and can be stably produced at low cost.

  The inventor further made the width of the antenna substrate 23 (the width direction of the band 100, that is, the length in the short direction of the band 100) about 15 mm. Thereby, the antenna board | substrate 23 can be accommodated in the storage part 10 of width 20mm, and also the following effects are acquired. That is, even when the center of the band 100 (particularly, the antenna substrate 23) and the reader / writer are shifted in the width direction of the band 100 within a range specified in the test related to the communication distance, the desired communication can be performed for the band 100. Performance can be ensured and passed the test. As is clear from FIG. 1 and the like, the antenna substrate 23 has a sufficient length in the longitudinal direction of the band 100. Therefore, even when the center of the band 100 and the reader / writer are shifted in the longitudinal direction of the band 100 within the range specified in the test related to the communication distance, the band 100 can ensure the desired communication performance.

  The verification is a test performed by a certification body in order to confirm that an IC card used as a part of infrastructure such as electronic money satisfies a predetermined communication performance.

  The inventor of the present application uses the above-described first and second contrivances to manufacture a conventional general IC card having a standard size (eg, short side: 53.89 mm, long side: 85.6 mm), Utilizing FPC manufacturing technology, a small band 100 having sufficient communication performance was realized.

(About IC card thickness)
In the above description, the IC card 21 forms an IC card manufactured on an IC card manufacturing line having the size of the conventional general IC card (short side: 53.89 mm, long side: 85.6 mm). It was supposed that it was manufactured. However, since the conventional general IC card is thick (usually 0.8 mm), the reaction force against bending is strong, and the internal IC chip 211 is likely to be damaged when bent. In particular, the IC chip 211 used for electronic money tends to have a large chip size in order to achieve high security, and is easily damaged by bending.

  Therefore, the inventors of the present application have made the thickness of the IC card 21 thinner than that of the conventional general IC card, and suppressed the force applied to the IC chip 211 when the IC card 21 is bent. Specifically, by setting the thickness of the IC card 21 to 0.5 mm, the force (stress) applied to the IC chip 211 when the IC card 21 is bent is suppressed, and the IC chip 211 is peeled off from the IC card 21. To prevent it. Further, since the change in the thickness of the IC card 21 has little influence on the IC card production line, it is unlikely to be a problem in manufacturing.

  That is, the inventor of the present application cuts out an IC card having a thickness of 0.5 mm manufactured on the IC card manufacturing line of the conventional general IC card size to a size that can be stored in the storage unit 10, An IC card 21 was formed.

  By performing the above-described device, the inventor of the present application utilizes the above-described conventional general IC card production line while avoiding breakage of the IC chip 211 when the IC card 21 is bent. The band 100 having a sufficient communication function (particularly, a communicable distance) has been successfully manufactured. The inventor of the present application further ensures stable communication with respect to the band 100 by performing the following device.

(About gaps for protecting electronic parts)
The inventor of the present application does not directly apply a physical load from the outside to the electronic components of the band 100, specifically, at least one of the IC chip 211 of the IC card 21 and the capacitor 231 of the antenna substrate 23. The following ideas were made. That is, an air gap is provided around at least one of the IC chip 211 and the capacitor 231 so that an external physical load is not directly applied to at least one of the IC chip 211 of the IC card 21 and the capacitor 231 of the antenna substrate 23.

  Specifically, a hole 221 is provided at a position corresponding to the capacitor 231 of the double-sided tape 22 for attaching the IC card 21 and the antenna substrate 23, and a lid for sealing the storage unit 10 storing the electronic substrate body 20. A recess 301 is provided at a position corresponding to the capacitor 231 on the lowermost surface of the body 30. By providing the hole 221 of the double-sided tape 22 and the recess 301 of the lid 30, physical load from the outside is prevented from being directly applied to the capacitor 231. That is, due to the gap (hole 221 and recess 301) provided around the capacitor 231, an external physical load is not directly applied to the capacitor 231, and damage to the capacitor 231 can be prevented.

  In the band 100, the hole 221 and the recess 301 are provided at a position corresponding to the capacitor 231. However, in the band 100, a hole may be further provided at a position corresponding to the IC chip 211 of the double-sided tape 22. . Further, a recess may be provided at a position corresponding to the IC chip 211 on the lowermost surface of the lid 30. Details will be described in Embodiment 2 with reference to FIGS. Next, a method for manufacturing the band 100 will be described with respect to the band 100 whose structure has been described above.

(Manufacturing process)
The outline of the manufacturing method of the band 100 will be described as follows. That is, the method for manufacturing the band 100 is a method for manufacturing a band-type communication terminal, in which the antenna substrate 23 including at least one of the capacitor 231 and the resistor, and the IC card 21 including the IC chip 211 are connected to the capacitor 231. The electronic substrate body 20 is formed by bonding with a double-sided tape 22 provided with a hole 221 at a position corresponding to at least one of the resistor and the IC chip 211, and formed in the forming step. The electronic substrate body 20 is stored in the storage unit 10 provided on the belt of the band and having an opening in the storage unit 10 in a state where the antenna substrate 23 is on the opening side, and stored in the storage unit 10 in the storage step. A substantially plate-like lid body 30 having a recess 301 on the surface facing the electronic substrate body 20 is superimposed on the electronic substrate body 20. Capacitor 231, the resistor, and arranged so as to correspond to at least one IC chip 211 includes, a closing step of closing the opening. Hereinafter, the details of the manufacturing method of the band 100 will be further described.

  First, a belt (annulated belt) that is an annular belt and is provided with the storage unit 10 in advance is prepared. The annular belt includes a portion in which the storage portion 10 is provided in advance, and a mounting portion 60.

  Second, the antenna substrate 23 and the IC card 21 are bonded together with a double-sided tape 22 having a hole 221 provided at a position corresponding to the capacitor 231 to form the electronic substrate body 20 (forming step). As described with reference to FIG. 2 and the like, the electronic substrate body 20 is a substantially plate-like laminate in which the IC card 21 and the antenna substrate 23 are bonded together with the double-sided tape 22. A hole 221 is provided at a position of the double-sided tape 22 corresponding to the capacitor 231 provided in the antenna substrate 23.

  Third, the electronic substrate body 20 formed in the forming step is stored in the molded belt storage unit 10 with the antenna substrate 23 facing the opening of the storage unit 10 (storage step). Here, the electronic substrate body 20 may be installed in the storage unit 10 in a state of being distorted in accordance with the curvature of the molded belt. That is, the electronic substrate body 20 may be stored in the storage unit 10 in a state of being distorted in accordance with the shape (substantially annular) of the band 100 as described below. For example, the surface of the electronic substrate body 20 that is distorted according to the shape of the band 100 is opposed to the bottom surface of the storage unit 10 (specifically, the surface of the IC card 21 that is opposed to the bottom surface of the storage unit 10). And a bottom surface of the storage unit 10 may be fixed by a double-sided tape (not shown). According to the above method, the electronic substrate body 20 can be fixed to the bottom surface of the storage unit 10 in a state where the electronic substrate body 20 is distorted in accordance with the shape of the belt of the band 100 (substantially annular).

  Fourth, the electronic substrate body 20 is overlapped with the electronic substrate body 20 fixed to the bottom of the storage unit 10 in a curved state in the storage step, and more precisely, the electronic substrate body 20 is overlaid on the opening side surface of the storage unit 10. Then, the lid 30 is disposed (blocking step). Here, a recess 301 is provided on the lowermost surface of the lid 30 (the surface facing the antenna substrate 23), and the lid 30 is placed on the electronic substrate body so that the recess 301 is disposed at a position corresponding to the capacitor 231. 20, the opening of the storage unit 10 is closed.

  Fifth, the melted resin material (specifically, the melted fixing member 40) is poured (filled) into the cutout portion 31 of the lid 30 to cure the resin material, and the lid 30 Is fixed to the inside of the storage portion 10 (fixing portion forming step). That is, the fixing member 40 is formed, and the storage unit 10 in which the electronic substrate body 20 and the lid body 30 are stored is sealed (sealed). Note that the melted fixing member 40 is filled in the notch 31 so that the surface of the fixing member 40 on the side contacting the wrist of the user wearing the band 100 coincides with the opening surface of the storage unit 10. . However, in the melted fixing member 40, the surface of the fixing member 40 on the side contacting the wrist of the user wearing the band 100 is more inside the opening of the storage unit 10 than the opening surface of the storage unit 10 (see FIG. 1). The notch 31 may be filled so as to be on the lower side of the paper surface in (b).

  In the closing step, the lid body 30 is disposed so as to overlap the electronic substrate body 20, and in the fixing portion forming step, the molten resin material (the molten fixing member 40) is notched 31 in the lid body 30. And between the inner wall of the storage unit 10. By performing the fixing part forming step after the closing step, the band 100 which is an injection molded product in which the electronic substrate body 20 is embedded and assembled can be stably obtained. According to the manufacturing method described above, the storage unit 10 and the mounting unit 60 can be formed of the same material for the belt of the band 100. That is, the storage unit 10 that stores the electronic substrate body 20 is provided on the belt of the band 100, and specifically, the storage unit 10 is provided in a concave shape on the back surface of the belt of the band 100. By the manufacturing method described above, the band 100 including the storage unit 10 as shown in FIG. 6 can be manufactured.

  FIG. 6 is a cross-sectional view showing a detailed structure of the storage unit 10 of the band 100. FIG. 6A is a cross-sectional view showing a detailed structure of the storage unit 10 of the band 100. FIG. 6B is an enlarged cross-sectional view of a portion L1 in FIG. FIG. 6C is an enlarged cross-sectional view of a portion L2 in FIG. As shown in FIGS. 6A to 6C, in the band 100, external physicality is provided by a gap (a hole 221 in the double-sided tape 22 and a recess 301 in the lid 30) provided around the capacitor 231. The mechanical load is not directly applied to the capacitor 231. Therefore, the band 100 can prevent the capacitor 231 from being damaged due to an external physical load applied directly to the capacitor 231.

  As shown in FIG. 6C, the storage unit 10 includes a recess 11 on the bottom surface of the storage unit 10 (a surface that contacts (opposes) the electronic substrate body 20, that is, the IC card 21). It may be. The depth D11 of the recess 11 is, for example, 0.2 mm. By providing the recess 11 on the bottom surface of the storage unit 10, the physical load applied to the IC chip 211 when the band 100 is bent can be suppressed, and the risk of breakage of the IC chip 211 can be further reduced.

  In addition, the band 100 in which the storage unit 10 and the mounting unit 60 are integrated has been described so far. That is, the band 100 in which the entire belt of the band 100 is integrally formed and the storage unit 10 is provided in a part of the integrally formed belt has been described so far. However, regarding the belt of the band 100, it is not essential that the storage unit 10 and the mounting unit 60 are integrated. For example, with respect to the belt of the band 100, the storage unit 10 and the mounting unit 60 may be formed of different materials. More specifically, for example, the belt of the band 100, polycarbonate (Poly Carbonate, hereinafter abbreviated as “PC”) is used for the storage unit 10, and TPU or silicon rubber is used for the mounting unit 60, for example. Good. By forming the storage unit 10 and the mounting unit 60 with different materials for the belt of the band 100, for example, the texture of the two can be made different, and the design possibilities of the band 100 can be expanded. Further, regarding the storage unit 10, the mechanical strength of the storage unit 10 can be improved as compared with the mounting unit 60 by using a material having a higher hardness than the material used for the mounting unit 60.

  In addition, as a method of filling the fixing member 40 between the cutout portion 31 of the lid 30 and the inner wall of the storage portion 10, the heat-melted fixing member 40 is connected to the cutout portion 31 and the storage portion of the lid 30. A method other than the method of pouring between the ten inner walls may be used. For example, an epoxy-based adhesive is used as the fixing member 40, and the fixing member 40 is poured between the notch 31 of the lid 30 and the inner wall of the storage unit 10 in a viscous state, and then cured by a chemical change. It is also possible to adopt a method of making them.

[Embodiment 2]
The following will describe another embodiment of the present invention with reference to FIGS. For convenience of explanation, members having the same functions as those described in the embodiment are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 7 is an exploded top view and an exploded sectional view showing the structure of the storage unit 110 of the band 200 according to the second embodiment of the present invention. FIG. 8 is a cross-sectional view showing the structure of the storage portion 110 of the band 200. As shown in FIGS. 7 and 8, in the band 200, in addition to the concave portion 301 provided at the position corresponding to the capacitor 231, the lowermost surface of the lid 130 (the surface in contact with (opposite with) the antenna substrate 23). In addition, a recess 302 is provided at a position corresponding to the IC chip 211. In addition to the hole 221 provided at the position corresponding to the capacitor 231, the double-sided tape 122 is further provided with a hole 222 at a position corresponding to the IC chip 211. Further, a recess 11 is provided at a position corresponding to the IC chip 211 on the bottom surface of the storage unit 110 (the surface that contacts (opposes) the IC card 21).

  In the band 200, a gap is provided around the IC chip 211 and the capacitor 231 so that an external physical load is not directly applied to the IC chip 211 and the capacitor 231. Specifically, the double-sided tape 122 is provided with a hole 221 at a position corresponding to the capacitor 231 and a hole 222 at a position corresponding to the IC chip 211. Further, on the lowermost surface of the lid 130, a recess 301 is provided at a position corresponding to the capacitor 231, and a recess 302 is provided at a position corresponding to the IC chip 211. Furthermore, a recess 11 is provided on the bottom surface of the storage unit 110 at a position corresponding to the IC chip 211. By providing the gap (hole 221, hole 222, recess 301, recess 302, and recess 11), the band 200 does not directly apply an external physical load to the IC chip 211 and the capacitor 231. Damage to the IC chip 211 and the capacitor 231 can be prevented.

  The band 200 described so far can be summarized as follows. That is, the band 200 is a band-type communication terminal, and is provided on a belt and has a storage unit 110 having an opening, an electronic board body 20 stored in the storage part 110, and the opening side of the electronic board body 20. And a substantially plate-like lid body 130 that closes the opening in a state of being placed on the electronic substrate body 20. The electronic substrate body 20 includes an antenna substrate 23 including at least one of a capacitor 231 and a resistor, and an IC. An IC card 21 including a chip 211 and a double-sided tape 122 that bonds the antenna substrate 23 and the IC card 21 are included. The double-sided tape 122 corresponds to at least one of the capacitor 231, the resistor, and the IC chip 211. It has a hole 221 and a hole 222 at the position, and the lid body 130 faces the electronic substrate body 20 in a state where the antenna substrate 23 is on the opening side. Of that surface, the capacitor 231 has the resistor, and the recess 301 and the recess 302 at positions corresponding to the at least one IC chip 211.

[Embodiment 3]
The following will describe another embodiment of the present invention with reference to FIGS. For convenience of explanation, members having the same functions as those described in the embodiment are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 9 is a diagram and a circuit diagram showing an outline of the antenna substrate 323 of the band 300 according to the third embodiment of the present invention. 9A is a diagram illustrating an outline of the antenna substrate 323 of the band 300, and FIG. 9B is a circuit diagram of the antenna substrate 323. The band 300 includes an antenna substrate 323 instead of the antenna substrate 23 of the band 100, and has the same configuration as the band 100 in other points. In FIG. 9A, a capacitor 231 is mounted on a capacitor mounting portion C surrounded by a wavy line. As will be described later, in the antenna substrate 323 of the band 300, the capacitor 231 is a composite capacitor formed by electrically connecting a first sub capacitor 232 and a second sub capacitor 233 in parallel.

  FIG. 10 is a diagram showing details of the antenna substrate of FIG. The antenna substrate 323 is a double-sided FPC board in which copper foil is bonded to both sides of polyimide, and FIG. 10A is an enlarged view of a capacitor mounting portion C surrounded by a wavy line in FIG. b) is a diagram showing a state of mounting the capacitor on the capacitor mounting portion C. FIG. FIG. 10C is a diagram showing a copper pattern on the front surface of the FPC in FIG. 9A, and FIG. 10D is a diagram showing a copper pattern on the back surface of the FPC in FIG. 9A. By connecting the copper pattern on the front surface of the FPC and the copper pattern on the back surface, a conductive antenna on the loop is formed.

  As shown in FIGS. 9 and 10, in the antenna substrate 323, like the antenna substrate 23 of the band 100, the FPC pattern forms a coil, and a capacitor 231 is connected in series to the resonance circuit ( An antenna pattern 340). Here, the capacitor 231 in the antenna substrate 323 is a composite capacitor formed by electrically connecting the first sub capacitor 232 and the second sub capacitor 233 in parallel. That is, “the capacitance of the capacitor 231 = the capacitance of the first sub-capacitor 232 + the capacitance of the second sub-capacitor 233”.

  In addition, in the double-sided FPC, the pattern formed of the copper foil is opposed to each other with the non-conductive polyimide interposed therebetween, and therefore there is a distributed capacitance not shown. Therefore, the resonance frequency of the antenna substrate 323 is determined by the inductance of the coil, the capacitance of the first sub capacitor 232, the capacitance of the second sub capacitor 233, and the distributed capacitance. Among these, the distributed capacitance varies depending on the FPC copper foil pattern, the type and thickness of polyimide as the FPC base material, the FPC manufacturing method, and the like. Therefore, the target resonance frequency is achieved by experimentally adjusting the capacitance of the capacitor 231 after designing the FPC pattern.

  Regarding the band 300 whose structural outline has been described above, the capacitance of the capacitor 231 (more precisely, the first sub-capacitor 232 and the second sub-capacitor 233) of the band 300 will be described with reference to FIG. I will explain in detail.

  FIG. 10 shows the communicable distance of the band 300, the resonance frequency of the antenna pattern 340 using only the first sub capacitor 232 or the second sub capacitor 233, and the first sub capacitor 232 and the second sub capacitor 233 for the antenna substrate 323. It is a figure which shows the resonant frequency of the antenna pattern 340 by the capacitor | condenser 231 which is a synthetic | combination capacitor | condenser electrically connected in parallel.

  In order to facilitate understanding of the capacitance of each of the capacitor 231, the first sub-capacitor 232, and the second sub-capacitor 233, the outline will be described first as follows. That is, in the band 300, the capacitor 231 includes an antenna pattern 340 (antenna) formed on the antenna substrate 323, which is formed by electrically connecting the first sub capacitor 232 and the second sub capacitor 233 (two sub capacitors) in parallel. Circuit) is set so that the communicable distance is equal to or greater than a predetermined distance, and each of the first sub-capacitor 232 and the second sub-capacitor 233 has only one of the antenna patterns 340. It has a capacitance set such that the resonance frequency is less than the predetermined distance.

  In other words, the band 300 is a band-type communication terminal, and includes a first sub capacitor 232 and a second sub capacitor 233 electrically connected in parallel so that the communicable distance is equal to or greater than a predetermined distance. The antenna substrate 323 is provided with the antenna pattern 340 in which the resonance frequency is set. The first sub capacitor 232 and the second sub capacitor 233 each have only one of the resonance frequencies of the antenna pattern 340 when the predetermined frequency is the predetermined frequency. The capacitance is set to be less than the distance.

  According to the above configuration, each of the first sub-capacitor 232 and the second sub-capacitor 233 has an electrostatic capacitance that is set so that the resonance frequency of the antenna pattern 340 is less than the predetermined distance when only one is provided. Has capacity. That is, when a defect (mounting failure) occurs in at least one of the first sub capacitor 232 and the second sub capacitor 233, the first sub capacitor 232 and The capacitance of the second sub capacitor 233 is set. Therefore, in the communication distance inspection for the band 300, a defect of the band 300 can be easily detected, and stable communication can be efficiently ensured for the band 300.

  That is, for example, in the communication distance inspection at the time of shipment of the band 300, it becomes possible to easily detect a manufacturing defect of the band 300, and thus stable communication can be efficiently ensured for the band 300.

  Note that it is rare that the capacitance of the capacitor 231 necessary to realize the resonance frequency of the antenna 323 that maximizes the communication distance matches the capacitance of a capacitor that is normally produced. Therefore, it is an electronic circuit design to achieve a desired capacitance for the capacitor 231 by combining two capacitors produced in a standard manner, such as a combination of the first sub capacitor 232 and the second sub capacitor 233. This is a widely used technique.

(Two items considered when realizing the band according to this embodiment)
In the band 300, the capacitance of the capacitor 231 (more precisely, the first sub-capacitor 232 and the second sub-capacitor 233) is set so that the resonance frequency of the antenna substrate 323 is desired in consideration of the following two points. It is determined to be a value (range).

  First, the capacitor 231 takes into account the fact that the resonance frequency of the antenna substrate 323 varies due to the characteristic variation of the capacitor 231 that occurs in the capacitor manufacturing process and the characteristic variation of the antenna substrate 323 that occurs in the antenna substrate manufacturing process. In other words, the target capacitance values of the first sub capacitor 232 and the second sub capacitor 233 are determined.

  Second, the target values of the capacitances of the first sub-capacitor 232 and the second sub-capacitor 233 are determined in consideration of the fact that the resonance frequency of the antenna substrate 323 varies as the antenna substrate 323 dries or absorbs moisture. Has been. That is, the inventor of the present application has found that when the FPC of the antenna substrate 323 is dry, the resonance frequency of the antenna substrate 323 increases, and when the FPC absorbs moisture, the resonance frequency of the antenna substrate 323 tends to decrease. This is presumed to be caused by an increase in the distributed capacitance due to the moisture absorption by the FPC. Therefore, the inventor of the present application has set a target resonance frequency (“ft” in FIG. 10) for the resonance frequency of the antenna substrate 323 when the FPC of the antenna substrate 323 is dry. In addition, the capacitances of the capacitor 231, that is, the first sub-capacitor 232 and the second sub-capacitor 233 are determined so that the resonance frequency of the antenna substrate 323 becomes the target resonance frequency.

  Considering the above two points, it is possible to maximize the allowable range related to the capacitance of the capacitor 231 (specifically, the first sub capacitor 232 and the second sub capacitor 233). Hereinafter, the two points will be described in detail. Before that, in order to facilitate understanding of the two points, the relationship between the communication distance of the band 300 (communication possible distance) and the resonance frequency of the antenna substrate 323 is as follows. First, I will explain.

(Relationship between communicable distance and resonance frequency)
The communication distance test of the band 300 checks whether the band 300 has a predetermined communication distance, but it is troublesome to check the communication distance of the band 300 every time during the development of the band 300. Here, regarding a communication terminal, it is known that there is a correlation between the frequency used for communication by the communication terminal and the communication distance of the communication terminal. Therefore, the communication distance of the communication terminal can be predicted by checking the frequency of the communication terminal.

  In order to confirm that the band 300 has a predetermined communication distance and the band 300 passes the communication distance test, the communication distance of the band 300 needs to satisfy a predetermined communication distance (specified communication distance). As described above, the confirmation of the resonance frequency of the antenna substrate 323 included in the band 300 can be used instead of the confirmation of whether or not the communication distance of the band 300 satisfies the above definition. Therefore, the inventor of the present application determines the frequency range (target frequency range) of the antenna substrate 323 for the band 300 to pass the communication distance test so that the (resonance) frequency of the antenna substrate 323 falls within the target frequency range. In addition, the capacitance of the capacitor 231 included in the antenna substrate 323 was determined. Specifically, the inventor of the present application determined the capacitance of the capacitor 231 by conducting the following examination.

  The inventor first tested the relationship between the communication distance of the band 300 (communication possible distance) and the resonance frequency of the antenna substrate 323, and between the communication distance of the band 300 and the resonance frequency of the antenna substrate 323, It was confirmed that there is a relationship shown in the graph of FIG. That is, the inventor of the present application requires that the frequency of the antenna substrate 323 be in the range of “13.570 MHz to 13.920 MHz” (hereinafter, “allowable resonance frequency range”) in order for the band 300 to pass the above communication distance test. Confirmed that it must be within the range.

  Next, the inventor of the present application considers the allowable resonance frequency range, and the resonance frequency of the antenna substrate 323 for the band 300 to pass the communication distance test, that is, to ensure a specified communication distance. The target range was determined to be “13.480 MHz to 13.950 MHz” (hereinafter abbreviated as “target frequency range”). Then, by setting the capacitance of the capacitor 231 to 32 pF (27 pF + 5 pF), it was confirmed that the resonance frequency of the antenna substrate 323 is within the target frequency range, and the communication distance of the band 300 satisfies the specified communication distance. .

(Determining the capacitance of the capacitor in consideration of fluctuations in the resonance frequency due to FFP moisture absorption)
However, the inventor of the present application further studied that the resonance frequency of the antenna substrate 323 also fluctuates as the degree of moisture absorption of the antenna substrate 323 (hereinafter also referred to as “humidity of the antenna substrate 323”) fluctuates. discovered. That is, when the experiment is performed with the humidity of the antenna substrate 323 lowered, the resonance frequency of the antenna substrate 323 exceeds the upper limit of 13.950 MHz, which is the target frequency range, by 50 KHz, and the communication distance of the band 300 is determined as described above. I discovered that the communication distance may not be met. That is, the resonance frequency of the antenna substrate 323 is not only due to variations in the characteristics of the capacitor 231 (for example, variations in the capacitance of the capacitor 231 that occur in the manufacturing process of the capacitor 231), but also due to moisture absorption by the antenna substrate 323 (FPC). The present inventor has discovered that it fluctuates.

  Therefore, the inventor of the present application considers not only that the resonance frequency of the antenna substrate 323 varies due to variations in the characteristics of the capacitor 231, but also that the resonance frequency of the antenna substrate 323 varies due to moisture absorption of the antenna substrate 323 (FPC). Various experiments relating to the capacitance of the capacitor 231 were conducted. Then, the inventor of the present application reduces the upper limit of the resonance frequency of the antenna substrate 323 at the time of drying by 120 KHz than when the capacitance of the capacitor 231 is 32 pF by setting the capacitance of the capacitor 231 to 34 pF. It was confirmed that the frequency could be 13.880 MHz. That is, the inventors of the present application confirmed that the resonance frequency of the antenna substrate 323 is within the allowable resonance frequency range even when the antenna substrate 323 is dried by setting the capacitance of the capacitor 231 to 34 pF. In addition, by setting the capacitance of the capacitor 231 to 34 pF, the resonance frequency of the antenna substrate 323 is within the target frequency range even if the degree of moisture absorption of the antenna substrate 323 varies, and the communication distance of the band 300 is reduced. It was confirmed that the communication distance specified above was satisfied.

  Note that “ft” (target resonance frequency) in FIG. 10 indicates the target value of the resonance frequency of the antenna substrate 323 when the antenna substrate 323 is dried. The capacitance of the capacitor 231, that is, the first sub-capacitor 232 and the second sub-capacitor 233 is determined so that the resonance frequency of the antenna substrate 323 becomes the target resonance frequency.

(A desired resonance frequency is achieved by the combined capacitance of two capacitors)
The inventor of the present application realizes the capacitance (eg, 34 pF) of the capacitor 231 in the band 300 by the combined capacitance of the capacitance of the first sub capacitor 232 and the capacitance of the second sub capacitor 233. ing. Specifically, the capacitor 231 is configured as a composite capacitor formed by electrically connecting a first sub capacitor 232 and a second sub capacitor 233 in parallel.

  Here, the inventor of the present application sets the condition that the combined capacitance of each of the first sub-capacitor 232 and the second sub-capacitor 233 is the capacitance of the capacitor 231 (eg, 34 pF). In addition, the capacitance of each of the first sub-capacitor 232 and the second sub-capacitor 233 is determined so as to satisfy the following conditions. That is, the first sub-capacitor 232 and the second sub-capacitor 232 and the second sub-capacitor 233 are arranged so that the resonance frequency of the antenna substrate 323 is out of the allowable resonance frequency range due to at least one defect (mounting defect) of the first sub-capacitor 232 and the second sub-capacitor 233. The capacitance of each of the sub capacitors 233 is determined. That is, both the resonance frequency of the antenna substrate 323 when only the first sub capacitor 232 is mounted and the resonance frequency of the antenna substrate 323 when only the second sub capacitor 233 is mounted surely satisfy the allowable resonance frequency range. The capacitances of the first sub-capacitor 232 and the second sub-capacitor 233 are determined so as to deviate from each other.

  Specifically, in FIG. 10, “f1” is a factor other than mounting failure of the first sub-capacitor 232 (eg, manufacturing variation of the capacitance of the second sub-capacitor 233, inductance L of the antenna substrate 323 during drying) This shows the resonance frequency of the antenna substrate 323 when the manufacturing variation of the antenna substrate 323 and the degree of moisture absorption of the antenna substrate 323 vary in the direction of lowering the resonance frequency of the antenna substrate 323. That is, “f1” indicates that the first sub-capacitor 232 has a mounting failure, and the capacitance of the second sub-capacitor 233 is the largest among the characteristic variations that can be assumed for the second sub-capacitor 233. In addition, the resonance frequency of the antenna substrate 323 that sufficiently absorbs moisture when the inductance L of the antenna substrate 323 is the largest among the characteristic variations that can be assumed for the antenna substrate 323.

  Similarly, “f2” is a factor other than defective mounting of the second sub-capacitor 233 (eg, manufacturing variation of the capacitance of the first sub-capacitor 232, manufacturing variation of the inductance L of the antenna substrate 323 during drying, antenna substrate This shows the resonance frequency of the antenna substrate 323 when the degree of moisture absorption of the H.323 and the like varies in the direction of decreasing the resonance frequency of the antenna substrate 323. That is, “f2” indicates that the second sub-capacitor 233 has a mounting failure, and the capacitance of the first sub-capacitor 232 is the largest among the characteristic variations that can be assumed for the first sub-capacitor 232. In addition, the resonance frequency of the antenna substrate 323 that sufficiently absorbs moisture when the inductance L of the antenna substrate 323 is the largest among the characteristic variations that can be assumed for the antenna substrate 323.

  By setting both f1 and f2 to be out of the allowable resonance frequency range, if a mounting failure of at least one of the first subcapacitor 232 and the second subcapacitor 233 on the antenna substrate 323 occurs, the communication distance of the band 300 Does not satisfy the prescribed communication distance. Therefore, a manufacturing defect of the band 300 can be easily determined.

(Organization of the band according to this embodiment)
The contents described so far can be summarized as follows. That is, the inventor of the present application has found that there is a relationship shown in FIG. 10 between the communication distance (communication possible distance) of the band 300 and the resonance frequency of the antenna substrate 323. In addition, the inventor of the present application creates characteristics variations (component variations) of the capacitor 231 (specifically, the first sub-capacitor 232 and the second sub-capacitor 233) and the antenna substrate 323, which occur in the manufacturing process, and the antenna substrate. The target resonance frequency (ft) is set for the resonance frequency of the antenna substrate 323 in consideration of the fluctuation of the resonance frequency of the antenna substrate 323 due to the moisture absorption state of the H.323. Then, the capacitances of the capacitor 231, that is, the first sub-capacitor 232 and the second sub-capacitor 233 are determined so that the resonance frequency of the antenna substrate 323 becomes the target resonance frequency.

  That is, in the band 300, the total capacitance (synthetic capacitance) of the capacitance of the first sub capacitor 232 and the capacitance of the second sub capacitor 233 becomes the capacitance of the capacitor 231. Yes. Theoretically, the resonance frequency of the antenna substrate 323 becomes the target resonance frequency (ft) due to the capacitance of the capacitor 231. Further, even when the resonance frequency of the antenna substrate 323 varies due to the characteristic variation (component variation) of the capacitor 231 and the antenna substrate 323 and the moisture absorption state of the antenna substrate 323, the resonance frequency of the antenna substrate 323 is It falls within the allowable resonance frequency range.

  Furthermore, in the band 300, when a failure occurs in at least one of the first sub-capacitor 232 and the second sub-capacitor 233, the first frequency is set so that the resonance frequency of the antenna substrate 323 is outside the allowable resonance frequency range. The capacitance of each of the sub capacitor 232 and the second sub capacitor 233 is determined. Therefore, the band 300 can easily determine a manufacturing defect of the band 300.

[Embodiment 4]
(Band manufacturing method according to this embodiment)
About the band 300 demonstrated so far, the manufacturing method can be arranged as follows. That is, the method for manufacturing the band 300 is a method for manufacturing a band-type communication terminal, which includes a first sub-capacitor 232 and a second sub-capacitor 233 that are electrically connected in parallel, and a communicable distance is a predetermined distance. Including the antenna substrate forming step of forming the antenna substrate 323 provided with the antenna pattern 340 having the resonance frequency set as described above, each of the first sub capacitor 232 and the second sub capacitor 233 includes only one of them. In this case, the antenna pattern 340 has a capacitance set so that the resonance frequency is less than the predetermined distance.

[Embodiment 5]
In the above example, for the belts of the bands 100, 200, and 300, the portion where the storage unit 10 and the storage unit 110 are provided and the mounting unit 60 (the portion where the storage unit 10 and the storage unit 110 are not provided) are integrated. An example has been described. That is, the entire belts of the bands 100, 200, and 300 are integrally formed, and the bands 100, 200, and 300 in which the storage unit 10 and the storage unit 110 are provided in a part of the integrally formed belt will be described. I went.

  However, it is not essential for the belts of the bands 100, 200, and 300 that the storage unit 10, the storage unit 110, and the mounting unit 60 are integrally formed. For example, the mounting unit 60 may be provided with a recess that is recessed in a direction opposite to the storage unit 10 and the storage unit 110 on the surface facing the storage unit 10 and the storage unit 110. In addition, with respect to the storage unit 10 and the storage unit 110, a convex portion that protrudes toward the mounting unit 60 may be provided on a surface facing the mounting unit 60. And about the belt of bands 100, 200, and 300, you may fit the said convex part of the storage part 10 and the storage part 110, and the said recessed part of the mounting part 60. FIG. With the above configuration, for the belts of the bands 100, 200, and 300, the storage unit 10, the storage unit 110, and the mounting unit 60 can be formed of, for example, different materials. The range of designs that can be realized can be expanded.

[Summary]
Communication terminals (bands 100, 200, and 300) according to aspect 1 of the present invention are band-type communication terminals, and are provided in a belt and have a storage unit (10, 110) having an opening and the storage unit. And an approximately plate-shaped lid (30, 130) that closes the opening in a state of being placed on the electronic substrate body on the opening side of the electronic substrate body. The electronic substrate body includes an antenna substrate (23) including at least one of a capacitor (231) and a resistor, an IC card (21) including an IC chip (211), and the antenna substrate and the IC card. Double-sided tape (22, 122) to be bonded, and the double-sided tape has holes (221, 222) at positions corresponding to at least one of the capacitor, the resistor, and the IC chip. And the lid is recessed at a position corresponding to at least one of the capacitor, the resistor, and the IC chip on a surface facing the electronic substrate with the antenna substrate facing the opening. (301, 302).

  According to the above configuration, at least one of the hole and the recess is provided around at least one of the capacitor, the resistor, and the IC chip, that is, a gap is provided. Due to the gap, the capacitor, the resistor, and the IC chip stored in the storage unit provided in the belt of the communication terminal may be physically extended even when the belt is bent and stretched. The direct load is not applied directly. Therefore, the electronic substrate body including at least one of the capacitor and the resistor and the IC chip is not likely to be damaged by bending or stretching of the belt, and stable communication can be efficiently performed for the communication terminal. Can be secured.

  In the communication terminal according to aspect 2 of the present invention, in the aspect 1, the thickness of the IC card may be 0.5 mm.

  According to said structure, since the thickness of the said IC card is made thin compared with the thickness (for example, 0.8 mm) of the conventional normal IC card, when the said IC card is bent, it becomes the said IC chip. The applied force (stress) can be suppressed. Therefore, when the IC card is bent, the possibility of the IC chip being peeled off from the IC card and being damaged can be suppressed, and stable communication can be efficiently ensured for the communication terminal.

  In the communication terminal according to aspect 3 of the present invention, in the aspect 1 or 2, the IC chip may be arranged so as not to overlap the capacitor and the resistor.

  According to the above configuration, the IC chip is disposed so as not to overlap the capacitor and the resistor. Therefore, even when the belt is bent and stretched, the IC chip is not connected to the capacitor. And it does not contact at least one of the resistors. Therefore, at least one of the capacitor and the resistor and the IC chip do not collide with each other and are damaged even when the belt is bent and stretched, and the like. Can be secured.

  In the communication terminal according to aspect 4 of the present invention, in any of the above aspects 1 to 3, the capacitor (231) includes two sub-capacitors (a first sub-capacitor 232 and a second sub-capacitor 233) electrically in parallel. The resonance frequency of the antenna circuit (antenna pattern 340) formed on the antenna substrate (323) is set so that the communicable distance is equal to or greater than a predetermined distance, and the two sub capacitors Each may have a capacitance set such that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance.

  According to the above configuration, each of the two sub-capacitors has a capacitance set so that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance. That is, when at least one of the two sub-capacitors is defective (mounting failure), the capacitances of the two sub-capacitors are set so that the resonance frequency of the antenna circuit is always outside a predetermined range. ing. Therefore, in the communication distance inspection with respect to the communication terminal, the defect of the communication terminal can be easily detected, and stable communication can be efficiently ensured for the communication terminal.

  A communication terminal (band 300) according to aspect 5 of the present invention is a band-type communication terminal, and includes two sub-capacitors (first sub-capacitor 232 and second sub-capacitor 233) electrically connected in parallel. Including an antenna substrate (323) on which an antenna circuit (antenna pattern 340) in which a resonance frequency is set so that a communicable distance is equal to or greater than a predetermined distance is provided, and each of the two sub capacitors is only one When the antenna circuit is provided, the resonance frequency of the antenna circuit is set to be less than the predetermined distance.

  According to the above configuration, each of the two sub-capacitors has a capacitance set so that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance. That is, when at least one of the two sub-capacitors is defective (mounting failure), the capacitances of the two sub-capacitors are set so that the resonance frequency of the antenna circuit is always outside a predetermined range. ing. Therefore, in the communication distance inspection with respect to the communication terminal, the defect of the communication terminal can be easily detected, and stable communication can be efficiently ensured for the communication terminal.

  A method for manufacturing a communication terminal (bands 100, 200, and 300) according to aspect 6 of the present invention is a method for manufacturing a band-type communication terminal, and includes an antenna substrate (23) including at least one of a capacitor (231) and a resistor. ) And an IC card (21) including an IC chip (211), a double-sided tape provided with holes (221, 222) at positions corresponding to at least one of the capacitor, the resistor, and the IC chip (22, 122) to form the electronic substrate body (20), and the electronic substrate body formed in the forming step is provided on the belt of the band and has a storage portion having an opening. (10, 110), a storage step of storing the antenna board in a state of being on the opening side, and the electric power stored in the storage unit in the storage step. A substantially plate-shaped lid body having a recess (301, 302) on the surface facing the electronic substrate body is superimposed on the substrate body, and the recess serves as at least one of the capacitor, the resistor, and the IC chip. A correspondingly arranged closing step for closing the opening.

  According to said method, there exists an effect similar to the aspect 1. FIG.

  A method for manufacturing a communication terminal (band 300) according to aspect 7 of the present invention is a method for manufacturing a band-type communication terminal, and includes two sub-capacitors (first sub-capacitor 232 and first sub-capacitor connected electrically in parallel). An antenna substrate forming step of forming an antenna substrate (323) including an antenna circuit (antenna pattern 340) having a resonance frequency set so that a communicable distance is equal to or greater than a predetermined distance. In addition, each of the two sub-capacitors has a capacitance set such that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance.

  According to said method, there exists an effect similar to aspect 5.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention. Furthermore, a new technical feature can be formed by combining the technical means disclosed in each embodiment.

  The present invention can be widely applied to a band-type communication terminal equipped with an IC chip.

DESCRIPTION OF SYMBOLS 10 Storage part 11 Recess 20 Electronic board body 21 IC card 22 Double-sided tape 23 Antenna board 30 Cover body 100 Band (communication terminal)
110 Storage Unit 122 Double-sided Tape 130 Lid 200 Band (Communication Terminal)
211 IC chip 221 hole 222 hole 231 capacitor 232 first sub capacitor 233 second sub capacitor 300 band (communication terminal)
301 Concave part 302 Concave part 323 Antenna substrate 340 Antenna pattern (antenna circuit)

Claims (7)

A band-type communication terminal,
A storage section provided on the belt and having an opening;
An electronic substrate body stored in the storage unit;
A substantially plate-like lid that closes the opening in a state of being placed on the electronic substrate body on the opening side of the electronic substrate body,
The electronic substrate body is
An antenna substrate including at least one of a capacitor and a resistor;
An IC card including an IC chip;
Including a double-sided tape for bonding the antenna substrate and the IC card;
The double-sided tape has a hole at a position corresponding to at least one of the capacitor, the resistor, and the IC chip;
The lid body has a concave portion at a position corresponding to at least one of the capacitor, the resistor, and the IC chip on a surface facing the electronic substrate body in a state where the antenna substrate is on the opening side. A communication terminal characterized by.   The communication terminal according to claim 1, wherein the IC card has a thickness of 0.5 mm.   The communication terminal according to claim 1, wherein the IC chip is disposed so as not to overlap the capacitor and the resistor. The capacitor is composed of two sub-capacitors electrically connected in parallel,
The resonance frequency of the antenna circuit formed on the antenna substrate is set such that the communicable distance is a predetermined distance or more,
Each of the two sub-capacitors has a capacitance set such that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance. The communication terminal as described in any one. A band-type communication terminal,
Comprising an antenna substrate on which an antenna circuit including two sub capacitors electrically connected in parallel and having a resonance frequency set so that a communicable distance is equal to or greater than a predetermined distance;
Each of the two sub-capacitors has a capacitance set such that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance. A method of manufacturing a band-type communication terminal,
An antenna substrate including at least one of a capacitor and a resistor and an IC card including an IC chip are attached to a double-sided tape having a hole provided at a position corresponding to at least one of the capacitor, the resistor, and the IC chip. Forming steps to form an electronic substrate body,
A storage step of storing the electronic substrate body formed in the forming step in a storage portion provided on the belt of the band and having an opening in a state where the antenna substrate is on the opening side;
A substantially plate-like lid body having a recess on a surface facing the electronic substrate body, overlaid on the electronic substrate body stored in the storage section in the storage step, the recess being the capacitor, the resistor, and A communication terminal manufacturing method comprising: a closing step that closes the opening by disposing the IC chip so as to correspond to at least one of the IC chips. A method of manufacturing a band-type communication terminal,
Including an antenna substrate forming step of forming an antenna substrate including two sub-capacitors electrically connected in parallel and provided with an antenna circuit in which a resonance frequency is set so that a communicable distance is equal to or greater than a predetermined distance ,
Each of the two sub-capacitors has a capacitance set so that the resonance frequency of the antenna circuit when only one of them is provided is less than the predetermined distance.

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