JP2012134796A - Portable terminal with battery pack authenticity determination function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable terminal with a battery pack authenticity determination function which is capable of managing identification information on battery packs with certainty even in a minute space close to a metal member while multifunctionalizing an antenna.SOLUTION: A battery pack (50) has: an RFID tag antenna (91) attached to a metal battery surface (52); and a first magnetic body (96) laid between an antenna part (92) of the antenna and the battery surface. A portable terminal main body (2) has: a circuit board that can perform authenticity determination of the battery pack; a lid member (22) having a lid inner surface (22b) opposed to the battery pack; a tag reader antenna part (82) attached to the lid member; a card antenna part (42) electrically connected to the tag reader antenna part directly and performing another wireless communication; and a second magnetic body (46) provided on the lid inner surface, and laid in a region between only the card antenna part and the battery surface, other than a laying range of the first magnetic body in the battery surface.

Description

  The present invention relates to a portable terminal with a battery pack authentication function that can be attached to and detached from a portable terminal body.

  Portable electronic devices such as mobile terminals such as mobile phones can be driven by power supplied from secondary batteries (battery packs), and battery packs are indispensable for their mobility. is there. The battery pack is configured to be detachable from the mobile terminal body. For example, a battery pack that has reached the end of its life can be replaced with a new battery pack.

If this new battery pack is a genuine product that has been properly designed by the manufacturer of the mobile device (or a person who has obtained permission to do so), the user of the mobile device must The battery pack can be used as a power source.
On the other hand, if it is not a genuine product, its use increases the possibility of malfunction of the mobile device and damages the internal electronic components, and the safety of the battery pack during charge / discharge is also guaranteed. Not.

Therefore, to ensure the safety of mobile terminal users, it is desirable not to use non-genuine battery packs, and it is necessary to prevent the use of such battery packs or monitor the use of non-genuine battery packs There is. And the authenticity of a battery pack may be determined using RFID (Radio Frequency IDentification).
Specifically, the battery pack is provided with an RFID tag antenna section and an IC chip. The battery pack identification information is managed and used by wireless communication between the battery pack antenna section and the reader / writer antenna section. To ensure the safety of people.

  Here, the above-described RFID is already used in, for example, wireless communication using a non-contact IC card, specifically, electronic money such as a traffic system, and has a known configuration with respect to a portable terminal. In other words, an antenna unit that can handle a plurality of uses is required inside a portable terminal capable of wireless communication related to the authenticity determination of these IC cards and battery packs. For this reason, it is conceivable to use a technique of an antenna unit that can be used for a plurality of applications while suppressing mutual interference (for example, see Patent Documents 1 and 2).

JP 2006-126901 A JP 2003-85519 A

By the way, in the battery pack described above, metal parts such as electrodes are used, and a metal case may be used, and these metal members become an obstacle to the wireless communication.
More specifically, in a generally used 13.56 MHz band or 125 kHz band RFID, when a metal member is present on the back side of the battery pack antenna portion, this metal member is the reader / writer side antenna. The electromagnetic wave irradiated from the part is reflected or absorbed to generate a demagnetizing flux, and the antenna communication sensitivity is lowered.

  In this case, even if a combined configuration of the above-described technology, that is, a configuration in which two large and small antenna units are electrically connected in series and a magnetic material is arranged on the back of the small antenna unit can be used. There is a problem that communication is still difficult. This is because the antenna communication sensitivity is lowered by a metal member in a large antenna portion where no magnetic material is disposed.

Thus, when the battery pack is close to the antenna unit, a separate measure for securing the wireless communication is necessary.
SUMMARY OF THE INVENTION Accordingly, the object of the present invention is to provide a battery pack with a function of determining whether or not the battery pack is identified, which can reliably manage the identification information of the battery pack even in a minute space close to a metal member, while eliminating the above-mentioned problems and increasing the functionality of the antenna. To provide a terminal.

  A first invention for achieving the above object is a portable terminal that performs wireless communication between an RFID tag on the battery pack side and a reader / writer on the portable terminal body side, and the battery pack is made of a metal battery component. And a tag antenna for an RFID tag attached to the surface of the battery constituent member, and a first magnetic body laid between the antenna portion of the tag antenna and the surface of the battery constituent member.

  On the other hand, the portable terminal body includes a circuit board capable of determining the authenticity of the battery pack, a lid member having a lid inner surface facing the mounted battery pack, and an antenna unit for a tag reader of a reader / writer attached to the lid member And a card antenna unit that is electrically connected directly to the tag reader antenna unit and performs radio communication different from the above-described radio communication, and is provided on the inner surface of the lid, and only the card antenna unit And a second magnetic body laid in a region between the surface of the battery constituent member and excluding the laying range of the first magnetic body on the surface of the battery constituent member.

The present invention focuses on the point that obstructs wireless communication with a magnetic material for RFID.
According to the first invention, the mobile terminal includes a mobile terminal body and a battery pack configured to be detachable from the mobile terminal body. The battery pack includes a metal battery component, for example, a metal case or a battery main body, and a battery main body that functions as a secondary battery such as an electrode is placed inside the case. On the other hand, an RFID tag is attached to the surface of the metal case or the electrode of the battery body.

Whether or not the installed battery pack is a genuine product is determined based on the result of wireless communication between the RFID tag on the battery pack side and the reader / writer on the mobile terminal body side on the circuit board of the mobile terminal body. (Battery pack authenticity determination).
Here, the RFID tag has a metal case or battery main body that forms the appearance of the battery pack on the back of the tag antenna, and the laying range is larger than the surface of the case or the area of the electrode of the battery main body. Therefore, the antenna communication sensitivity of the antenna unit is lowered by the surface of the case or the electrode of the battery body.

  On the other hand, an antenna including a tag reader antenna unit and a card antenna unit is attached to the lid member. The tag reader antenna unit performs wireless communication regarding the authenticity determination of the battery pack with the tag antenna, and the card antenna unit performs wireless communication different from the authentication determination with, for example, an external card reader antenna. However, the tag reader antenna unit and card antenna unit are electrically connected in series, so that multiple antenna functions can be achieved, and the number of terminals can be reduced by using a common terminal. Become.

  By the way, since this tag reader antenna portion also faces the tag antenna, the laying range thereof becomes smaller than the surface of the case or the area of the electrode of the battery body. Further, the surface of the case or the electrode of the battery body is present in front of the card antenna. That is, in this case, the antenna communication sensitivity for both the reader and the card is lowered by the surface of the case or the electrode of the battery body.

  However, in the present invention, the surface of the case or the electrode of the battery body is first covered by combining the laying range of the first magnetic body on the tag antenna side and the laying range of the second magnetic body on the card antenna side. The communicable direction of the tag reader antenna unit and the communicable direction of the card antenna unit can be made different, and any deterioration in antenna communication sensitivity can be prevented.

  Specifically, if the second magnetic body is laid not only between the tag reader antenna portion and the case surface or the battery body electrode, but only between the card antenna portion and the case surface or the battery body electrode, This is because the second magnetic body attracts the magnetic flux even when wireless communication obstruction factors are close to each other, and the magnetic flux penetrates between the external card reader antenna and the card antenna portion described above.

If the first magnetic body is laid between the antenna portion of the tag antenna and the surface of the case or the electrode of the battery body, the first magnetic body attracts the magnetic flux even if the wireless communication obstruction factor is close. This is because magnetic flux penetrates between the tag reader antenna unit and the tag antenna.
According to a second invention, in the configuration of the first invention, a metal sheet that is disposed on the opposite side of the tag reader antenna portion across the tag reader antenna portion and covers only the tag reader antenna portion, and these And a third magnetic body laid between the metal sheet and the tag reader antenna.

  According to the second invention, in addition to the operation of the first invention, the third magnetic body is further laid between the metal sheet and the tag reader antenna, and the metal sheet is used for wireless communication. Therefore, the communicable direction of the tag reader antenna unit can be secured. And the metal sheet | seat can prevent reliably that the communication content regarding the authenticity determination of a battery pack leaks outside.

According to a third aspect of the present invention, in the configuration of the first or second aspect, the tag reader antenna unit and the card antenna unit are electrically connected directly and wound in a spiral shape. It is arrange | positioned inside the card | curd antenna part, It is characterized by the above-mentioned.
According to the third invention, in addition to the effects of the first and second inventions, if the tag reader antenna unit and the card antenna unit are continuously connected on the inner side and the outer side, each antenna is provided separately. The number of spiral turns can be reduced compared to the case where the antenna is installed, and the laying range of each antenna can be reduced. Therefore, a portable terminal having a multifunctional space-saving antenna can be provided.

According to a fourth aspect of the present invention, in the configurations of the first to third aspects, the tag reader antenna portion and the card antenna portion are attached to the outer surface of the lid member exposed to the outside or the inner surface of the lid member. .
According to the fourth invention, in addition to the effects of the first to third inventions, the tag reader antenna unit and the card antenna unit connected in series are formed on the same surface of the lid member. As compared with the case where each is provided on a different surface, its manufacture becomes easier.

According to a fifth aspect, in the configurations of the first to fourth aspects, the card antenna unit performs non-contact wireless communication with an external reader / writer.
According to the fifth invention, in addition to the effects of the first to fourth inventions, the tag reader antenna unit and the card antenna unit connected in series can be used for non-contact wireless communication in addition to authenticating the battery pack. For example, it can handle a wide range of communications such as transportation and credit electronic money.

  According to the present invention, since the laying range of the tag magnetic body and the laying range of the card magnetic body are combined to cover the surface of the case or the electrode of the battery main body, the obstruction factor of wireless communication can be eliminated, and the metal It is possible to provide a portable terminal with a battery pack authenticity determination function capable of reliably managing battery pack identification information even in a minute space close to a manufactured member.

It is an external appearance perspective view of the mobile telephone provided with the authenticity determination function of the battery pack in a present Example. FIG. 2 is a perspective view in which the mobile phone of FIG. 1 is folded and the back side thereof is directed upward. FIG. 3 is a diagram in which a battery pack cover is removed from FIG. 2. It is a figure which shows the taking-out state of the battery pack in FIG. It is an external appearance perspective view of the battery pack of FIG. It is sectional drawing of the storage part periphery which follows the VI-VI line of FIG. It is a top view of the battery pack cover of FIG. 6, (a) is a base film, (b) is an antenna for a card | curd and a reader antenna, (c) is explanatory drawing of the RFID magnetic member for cards. It is a top view of the battery pack of FIG. 6, (a) is a RFID tag, (b) is a base film, (c) is explanatory drawing of the RFID magnetic member for tags. It is sectional drawing of the storage part periphery in another example. It is explanatory drawing of the antenna for cards and the antenna for readers of 2nd Example. It is a top view of the battery pack cover of 3rd Example, (a) is a metal sheet, (b) is explanatory drawing of the RFID magnetic member for readers. It is explanatory drawing of the antenna for card | curds and the antenna for reader | leaders in still another example.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings.
FIG. 1 shows a mobile phone (mobile terminal) 1 having a battery pack authenticity determination function. The mobile phone 1 includes a telephone main body (mobile terminal main body) 2 separated into a display side and an operation side.
Specifically, first, a thin and flat housing 3 is arranged on the display side, and this housing 3 has an inner surface 4 slightly larger than a business card, for example.

A main screen 5 is provided at the center of the inner surface 4 and can display various information such as user operation contents. In addition, an earpiece 6 and an illuminance sensor (not shown) are provided above the main screen 5 as viewed in FIG.
The housing 3 is connected to the outer surface 7 on the back side of the inner surface 4, and a sub-screen 8 for displaying time and the like is installed on the outer surface 7. Note that an antenna (not shown) that is used during a call or the like is built in the housing 3 on the back side of the earpiece 6.

The housing 3 is connected to the operation side on the opposite side of the earpiece 6 across the main screen 5.
A housing 10 having a hinge 9 is disposed on the operation side, and the housing 3 is rotatably connected to the housing 10 via the hinge 9. The housing 10 is slightly longer than the housing 3, but is also thin and flat, and has an inner surface 14 that is slightly larger than, for example, a business card.

A plurality of operation keys 15 used for various operations by the user are arranged on the inner surface 14, and a mouthpiece 16 is provided below the operation keys 15 as viewed in FIG. 1.
The housing 10 is also connected to the outer surface 17 on the back side of the inner surface 14, and when the housing 3 rotates toward the housing 10 from the state of FIG. 1 and the inner surface 4 and the inner surface 14 face each other, the telephone body 2 is about half as long. It will be in the folded state (FIG. 2).

  As shown in FIG. 2, a speaker 18, a camera lens unit 19, and a camera activation lamp 20 are provided on the outer surface 17 of the housing 10 around the hinge 9. In addition, an antenna (not shown) that is used during a call or the like is also built in the housing 10 on the back side of the hinge 9. Reference numeral 21 denotes a cap 21 that covers an external connection terminal that can be connected to an AC adapter or a USB cable.

  On the outer surface 17, a battery pack cover (lid member) 22 is provided between the cap 21 and the camera activation lamp 20. The battery pack cover 22 covers the surface of the battery pack 50 attached to the housing 10, as can be easily understood by adding FIG. 3 to FIG. A plurality of convex portions (not shown) are formed on the periphery of the battery pack cover 22, and when these convex portions engage with the concave portions 33 a and 34 a shown in FIGS. 3 and 4, the cover outer surface (lid outer surface) of the battery pack cover 22. 22 a is flush with the outer surface 17.

The battery pack cover 22 has a charging terminal 23 (FIGS. 2 and 3). The charging terminal 23 is used when the battery pack 50 is charged using a desktop holder.
On the other hand, when the battery pack 50 is also removed from the housing 10 as shown in FIG. 4 in the state shown in FIG. 3, that is, with the battery pack cover 22 removed from the housing 10, the storage portion 30 and the like can be visually recognized from the outside. Become.

Specifically, the storage unit 30 of the present embodiment has a rectangular opening facing the battery pack cover 22, and four storage unit side surfaces 31 to 34 are connected to the opening, and the tube is recessed toward the housing 3. A concave shape is formed.
First, the storage portion side surface 31 on the terminal side and the storage portion side surface 32 on the tab receiving side are arranged so as to intersect the longitudinal direction of the housing 10 (FIG. 4), and a space corresponding to the length of the rectangular battery pack 50 is formed. Opposite across.

On the other hand, as shown in FIG. 3, the right storage unit side surface 33 and the left storage unit side surface 34 are arranged along the longitudinal direction of the housing 10, and these are opposed to each other with a space corresponding to the width of the rectangular battery pack 50 interposed therebetween. To do.
More specifically, the storage side surface 31 on the terminal side is located in the vicinity of the camera activation lamp 20 and intersects the right storage side surface 33 and the left storage side surface 34 at both left and right ends thereof. Fixing holes 36 and 36 for the battery pack 50 are recessed toward the hinge 9 at intersections with the right and left storage side surfaces 33 and 34 (FIG. 4).

  Further, a main body side terminal 37 is installed near the side wall 33 on the right side as viewed in FIG. 4 of the side wall 31 on the terminal side. The main body side terminal 37 is electrically connected to the battery pack 50 attached to the storage unit 30. Further, a holder 38 for storing a user IC card 39 is provided near the left side storage portion side surface 34 of the terminal side storage portion side surface 31.

Next, as shown in FIGS. 3 and 4, the right and left storage unit side surfaces 33 and 34 have their central portions slightly bulging toward the outside of the storage unit 30. The above-described concave portions 33 a and 34 a are formed around each of the bulging portions, and engage with the convex portions of the battery pack cover 22.
The right and left storage side surfaces 33, 34 extend in the longitudinal direction of the housing 10 and intersect the storage side 32 on the tab receiving side.

  The tab receiving side surface 32 on the tab receiving side is disposed in the vicinity of the cap 21, and the four storage side surfaces 31 to 34 surround the battery side surfaces 61 to 64 of the battery pack 50 of FIG. 5. Note that the tab receiving side surface 32 on the tab receiving side has a curved portion 32a that is slightly depressed in a direction away from the terminal side storing portion side surface 31 (FIG. 4), and can accommodate the tab 78 of the battery pack 50. The user's fingertip can also be received when the battery pack 50 is taken out.

The battery pack 50 of the present embodiment is a lithium ion battery configured to be detachable from the storage unit 30.
As shown in FIG. 5, the battery pack 50 includes a rectangular case (battery constituent member) 51. The case 51 is made of metal (for example, aluminum laminate material), and has a wide battery surface (surface of the battery constituent member) 52 that faces the battery pack cover 22 when the case 51 is mounted.

The case 51 also has a wide battery back surface 53 below the battery surface 52 as seen in FIG. 5, and this battery back surface 53 faces the bottom portion of the recess when mounted on the storage unit 30.
The peripheral edges of the battery front surface 52 and the battery back surface 53 are connected to the four battery side surfaces 61 to 64, respectively, and face the four storage unit side surfaces 31 to 34 at the time of mounting.

  Specifically, the battery side 61 on the terminal side and the battery side 62 on the tab side face each other in the length direction of the battery pack 50, while the battery side 63 on the right side and the battery side surface on the left side as viewed in FIGS. 64 is opposed to the battery pack 50 in the width direction. Further, both ends of the battery side 61 on the terminal side and the battery side 62 on the tab side intersect with the battery side 63 on the right side and the battery side 64 on the left side, respectively.

As shown in FIG. 5, the battery pack 50 of this embodiment has a length from the battery side 61 on the terminal side to the battery side 62 on the tab side, and a width from the battery side 63 on the right side to the battery side 64 on the left side. It is formed smaller than.
The battery side 61 on the terminal side has a battery side terminal 77 near the battery side 63 on the right side. When the battery side terminal 61 is attached to the storage unit 30, the storage unit is connected via the body side terminal 37 of the storage unit side surface 31. It is electrically connected to a circuit board (not shown) arranged in the vicinity of 30.

Further, the battery side 61 on the terminal side has resin fixing claws 76, 76 at the intersections with the right battery side 63 and the left battery side 64. , Engage with the fixing holes 36 when the storage unit 30 is mounted.
The battery side 62 on the tab side has a resin tab 78 that is received by the curved portion 32a of the storage portion side 32 on the tab receiving side.

  The case 51 includes a battery body, that is, a negative electrode member made of, for example, graphite, a positive electrode member made of lithium transition metal oxide (for example, a composite material of manganese and nickel), and an electrolyte (organic solvent or gel). And a solid polymer electrolyte), and during discharge, lithium ions move from the negative electrode to the positive electrode and the battery reaction proceeds, while during charging, lithium ions move from the positive electrode to the negative electrode and the battery reaction Advances.

As described above, if an aluminum laminate material is used for the case 51, the manufacturing cost of the battery pack 50 can be suppressed. However, the battery main body having the negative electrode member, the positive electrode member, and the electrolyte is made of aluminum or iron. It can also be stored in a can.
In addition, a resin or paper insulating seal 74 is affixed to the case 51 (FIG. 5).

  The insulating seal 74 is wound by one turn along the width direction of the battery pack 50. In actual terms, the battery surface 52, the right battery side surface 63, the battery back surface 53, and the left battery side surface 64 are insulated. A portion not covered by the seal 74 is visible. In addition to the model name, output voltage, and capacity information of the battery pack 50, the insulating seal 74 also describes the mounting direction of the battery pack 50 and the like.

Here, the battery pack 50 includes an RFID tag 90 (FIGS. 3 to 5).
Specifically, the RFID tag 90 of the present embodiment is a passive type that does not have a power source, and an IC chip 94 is embedded in the central portion thereof as shown in FIG. The IC chip 94 has a function of rewriting / adding data to the memory, and is connected to the tag antenna 91.

The tag antenna 91 of the present embodiment is disposed on the battery surface 52. For example, the tag antenna 91 is disposed in the vicinity of the intersection of the battery side surface 63 on the right side and the battery side surface 62 on the tab side. Yes.
The tag antenna 91 includes a loop antenna (antenna portion) 92 having a conductor of a plurality of turns wound spirally, and an antenna substrate 93 on which the loop antenna 92 is placed.

  The loop antenna 92 is a magnetic field type antenna that performs radio communication using an electromagnetic induction method, for example, a 13.56 MHz frequency band (short wave: HF band) and radiates electromagnetic waves toward a reader / writer 80 described later. The loop antenna 92 is formed on the antenna substrate 93 by a transfer method or the like, and the laying range thereof is provided in an area (for example, 10 mm × 10 mm) smaller than the area of the battery surface 52.

  As described above, the tag antenna 91 according to the present embodiment has the battery surface 52 of the case 51 disposed on the back surface of the loop antenna 92, and the laying range is smaller than the area of the battery surface 52. Although the communication sensitivity is lowered by the case 51, in this embodiment, the RFID magnetic member for tag (first magnetic body) 96 prevents the antenna communication sensitivity from being lowered.

  Specifically, the antenna substrate 93 has an insulating resin base film 95 on which the loop antenna 92 is placed, as shown in FIG. 6 and FIG. As shown in (c), a tag RFID magnetic member 96 is provided on the opposite side of the loop antenna 92 with the base film 95 interposed therebetween, that is, on the back side of the base film 95.

6 is a cross-sectional view of the periphery of the storage unit 30 along the line VI-VI in FIGS. 2 and 7. In FIG. 6, in order to help understand the structure of the antenna substrate 93, The thickness of the RFID magnetic member 96 for tags is particularly emphasized.
The base film 95 is made of a thermoplastic resin in a flat plate shape, for example, and has a thickness of about 50 μm (1 μm = 1 × 10 ⁻⁶ m).

Next, the RFID magnetic member 96 for tags is provided in the laying range of the loop antenna 92. For example, an insulating film is interposed between two magnetic films, and flat films are alternately laminated. The RFID magnetic member 96 for tags is formed by a physical vapor deposition method, for example, and has a thickness of about 10 μm.
Further, the tag antenna 91 of this embodiment is covered with an insulating seal 74 from above the loop antenna 92 and fixed to the battery surface 52 (FIG. 6).

Therefore, although the tag antenna 91 is slightly raised from the battery surface 52, it is hidden by the insulating seal 74 on which information such as the battery pack 50 is written. The battery pack cover 22 is removed and the battery of the battery pack 50 is temporarily removed. Even if the surface 52 side is seen, the RFID tag 90 cannot be visually recognized.
The RFID tag 90 may be visible from the outside by providing the RFID tag 90 on the insulating seal 74 and removing the battery pack cover 22.

By the way, electronic components such as a CPU, a memory, and a chip for operating the mobile phone 1 are mounted on the circuit board described above, and whether or not the battery pack 50 attached to the storage unit 30 is a genuine product. A control unit for judging is also mounted.
Specifically, this control unit is a constituent element of the reader / writer 80, and authenticates the battery pack 50 based on the result of wireless communication between the tag reader antenna 81 of the reader / writer 80 and the RFID tag 90. it can.

The tag reader antenna 81 of this embodiment is disposed on the cover outer surface 22a of the battery pack cover 22 (FIG. 6).
Specifically, the tag reader antenna 81 includes a loop antenna (tag reader antenna portion) 82 having a multi-turn conductor wound in a spiral shape, and an antenna substrate 43 on which the loop antenna 82 is placed. The

  The loop antenna 82 is also a magnetic field antenna and is formed on the antenna substrate 43 by a transfer method or the like. Further, the laying range is provided with an area (for example, 10 mm × 10 mm) smaller than the area of the battery surface 52, and the loop antenna 82 is disposed at a position completely overlapping the loop antenna 92 of the tag antenna 91 (see FIG. 6, FIG. 7 (b), FIG. 8 (a)).

On the other hand, the antenna substrate 43 is configured to be wider than the laying range of the loop antenna 82 and further extends along the length direction and the width direction of the battery pack 50 (FIGS. 6 and 7A). A card antenna 41 is also laid.
The card antenna 41 of this embodiment performs non-contact wireless communication with an external reader / writer (not shown), and can be used for, for example, transportation electronic money.

  Specifically, the card antenna 41 has a loop antenna (card antenna unit) 42 having a plurality of turns of a conductor wound in a spiral manner, similarly to the loop antennas 82 and 92. On the other hand, the laying range of the loop antenna 42 is provided with an area (for example, 40 mm × 30 mm) substantially equal to the area of the battery surface 52 (FIG. 7B).

  Here, the loop antenna 42 of the card antenna 41 and the loop antenna 82 of the tag reader antenna 81 are electrically directly connected to each other, and are connected in series, as shown in FIG. 7B. In addition, the loop antenna 82 of the tag reader antenna 81 is disposed inside the loop antenna 42 of the card antenna 41.

  The end portion of the loop antenna 42 and the end portion of the loop antenna 82 that are continuously connected are pulled out toward the storage portion side surface 33 on the right side. Therefore, when the battery pack cover 22 is attached to the housing 10, the cover inner surface (lid inner surface) 22b of the battery pack cover 22 faces the battery surface 52, and the tag reader antenna 81 and the card antenna 41 are arranged on the right side of the storage unit. The circuit board can be electrically connected to the control unit of the circuit board and the user IC card 39 via wiring patterns (not shown) 33.

As described above, the card antenna 41 of the present embodiment has the battery surface 52 disposed in front of the loop antenna 42, so that the antenna communication sensitivity is also reduced by the case 51. The RFID magnetic member (second magnetic body) 46 prevents a decrease in antenna communication sensitivity.
Specifically, the antenna substrate 43 has an insulating resin base film 45 on which the loop antennas 42 and 82 are placed on the cover outer surface 22a, as shown in FIGS. 6 and 7A. As shown in FIGS. 6 and 7C, a card RFID magnetic member 46 is provided on the back side of the cover outer surface 22a, that is, on the cover inner surface 22b.

The loop antennas 42 and 82 may be integrated by being embedded in the cover outer surface 22a by printing or insert molding. Also, in FIG. 6, the thickness of the base film 45 and the RFID magnetic member 46 for cards is particularly emphasized in order to help understand the structure of the antenna substrate 43.
The base film 45 is also formed in a flat plate shape with, for example, a thermoplastic resin having a thickness of about 50 μm.

  Next, in the same way as the RFID magnetic member 96 for the tag, the RFID magnetic member for card 46 has, for example, an insulating film interposed between two magnetic films, and flat films are alternately laminated. 22b is integrated by printing or sputtering, but is laid out in a region excluding the laying range of the RFID magnetic member 96 for tags (FIG. 6 and FIG. 7C), and the RFID magnetic member 46 for cards. The laying area of the base film 45 is formed in a size obtained by removing the laying area of the tag RFID magnetic member 96 from the laying area of the base film 45.

  In other words, the RFID magnetic member for card 46 in FIG. 7C does not directly cover the battery surface 52 unlike the RFID magnetic member 96 for tag in FIG. When the laying range of 96 and the laying range of the RFID magnetic member for card 46 are combined in the depth direction of the storage portion 30, the battery surface 52 can be covered for the first time.

That is, as shown in FIG. 7C, when viewed from the outside 17 of the telephone body 2 through the battery pack cover 22, the battery surface 52 has the tag RFID magnetic member 96 and the card RFID magnetic member 46. It is covered with and disappears.
The card RFID magnetic member 46 is also formed, for example, by physical vapor deposition, as in the case of the tag RFID magnetic member 96, and is formed to a thickness of about 10 μm. High communication output can be obtained while reducing the total thickness of the film.

That is, first, in the RFID tag 90, the RFID magnetic member 96 for tags is inserted between the loop antenna 92 and the battery surface 52, and a communication distance of several mm can be obtained.
More specifically, the magnetic flux from the tag reader antenna 81 passes through the tag RFID magnetic member 96, and magnetic field coupling occurs between the loop antenna 82 and the loop antenna 92 to form a reflux magnetic flux.

As a result, even when wireless communication is performed in a minute space close to the battery surface 52, magnetic coupling occurs between the tag reader antenna 81 and the tag antenna 91, and an induced electromotive force is generated in the loop antenna 92. Then, the IC chip 94 is activated.
On the other hand, the answer signal from the IC chip 94 is received by the tag reader antenna 81 and output to the control unit of the circuit board.

As a result, non-contact wireless communication is enabled inside the mobile phone 1, that is, between the reader / writer 80 on the telephone body 2 side and the RFID tag 90 on the battery pack 50 side. 50 ID authentication makes it possible to determine whether or not the battery pack 50 attached to the storage unit 30 is a genuine product.
Further, also in the card antenna 41, the card RFID magnetic member 46 is inserted between the loop antenna 42 and the battery surface 52, and a communication distance of several centimeters is obtained.

For this reason, the magnetic flux from the external reader / writer described above, that is, the card reader antenna (not shown) passes through the card RFID magnetic member 46 and is magnetically coupled with the loop antenna 42 to generate a return magnetic flux. Can be formed.
Therefore, even when wireless communication is performed at a position close to the battery surface 52, magnetic coupling occurs between the external card reader antenna and the card antenna 41, and an induced electromotive force is generated in the loop antenna 42. Can communicate with an external card reader.

  Incidentally, the tag reader antenna 81 and the card antenna 41 may be attached to the cover inner surface 22b (FIG. 9).

  Specifically, FIG. 9 corresponds to a cross-sectional view around the storage unit 30 taken along the line VI-VI in FIGS. 2 and 7, but the same reference numerals are given to configurations having the same functions as those in the embodiment up to FIG. 8. If the description thereof is omitted, the tag reader antenna 81 and the card antenna 41 shown in FIG. 9 are provided on the same side as the card RFID magnetic member 46, that is, the loop antennas 42 and 82 are also provided on the cover inner surface 22b. ing.

  The card RFID magnetic member 46 is disposed on the back side of the base film 45 on which the loop antennas 42 and 82 are placed, and is laid out in a region excluding the laying range of the tag RFID magnetic member 96. When the laying range of the RFID magnetic member 96 and the laying range of the card RFID magnetic member 46 are combined in the depth direction of the housing 10, the battery surface 52 is first covered.

In this case, the loop antennas 42 and 82 may be integrated by printing or insert molding on the cover inner surface 22b, and the loop antennas 42 and 82, the base film 45, and the RFID magnetic member 96 for tag may be integrated. They may be integrated and insert molded or affixed to the cover inner surface 22b.
On the other hand, the loop antenna 82 of the tag reader antenna 81 may not be arranged inside the loop antenna 42 of the card antenna 41.

  That is, if the loop antenna 42 and the loop antenna 82 are connected in a row and the RFID magnetic member for card 46 is laid out in an area excluding the laying range of the RFID magnetic member for tag 96, FIG. As shown in FIG. 10, the loop antenna 82 may be configured as a part of the loop antenna 42 and may be disposed at a position that partially overlaps the loop antenna 92 of the tag antenna 91.

Furthermore, the loop antenna 82 of the tag reader antenna 81 may be covered with a metal sheet (metal sheet) 87 (FIG. 11).
Specifically, FIG. 11 corresponds to the example of FIGS. 6 and 7A in which the base film 45 and the loop antennas 42 and 82 are provided on the cover outer surface 22a. The metal sheet 87 covers only the loop antenna 82 on the opposite side of the tag antenna 91 across the loop antenna 82, in this embodiment, above the base film 45 disposed on the cover outer surface 22a (see FIG. 11 (a)).

An RFID magnetic member for reader (third magnetic body) 86 having the same laying area as that of the metal sheet 87 is provided on the back side of the metal sheet 87, that is, between the metal sheet 87 and the loop antenna 82. 45 (FIG. 11 (b)).
Note that the metal sheet 87 and the reader RFID magnetic member 86 can also be applied to the embodiment of FIG. 9 in which the base film 45 and the loop antennas 42 and 82 are provided on the cover inner surface 22b. The magnetic member 86 is disposed on the cover outer surface 22a, and the metal sheet 87 is disposed on the reader RFID magnetic member 86.

Furthermore, in each of the above-described embodiments, the battery pack cover 22 is configured separately from the outer surface 17 (FIG. 12A).
However, as long as the battery pack 50 is covered, a back cover (cover member) 22A that covers the entire back side of the telephone body 2 may be used as shown in FIG. In this case, the card RFID magnetic member 46 is laid in a region of the battery surface 52 excluding the laying range of the tag RFID magnetic member 96 (indicated by a one-dot chain line in the figure). The loop antenna 42 can be laid over the entire area of the back cover 22A.

  As described above, according to each of the embodiments described above, the mobile phone 1 includes the telephone main body 2 and the rectangular battery pack 50 configured to be detachable from the telephone main body 2. The battery pack 50 includes a metal case 51, and a battery body that functions as a secondary battery is housed inside the case 51. On the other hand, an RFID tag 90 is attached to the outside of the case 51.

Whether the battery pack 50 attached to the storage unit 30 is a genuine product or not is determined based on the result of wireless communication between the RFID tag 90 on the battery pack 50 side and the reader / writer 80 on the telephone body 2 side. The determination is made on a circuit board disposed around 30 (battery pack authenticity determination).
However, since the RFID tag 90 has a metal case 51 that forms the appearance of the battery pack 50 on the back surface of the loop antenna 92, and the laying range of the loop antenna 92 is smaller than the area of the battery surface 52, By this case 51, the antenna communication sensitivity of the loop antenna 92 is lowered.

  On the other hand, the loop antenna 82 and the loop antenna 42 are attached to the battery pack cover 22 (or the back cover 22A). The loop antenna 82 performs wireless communication related to the authenticity determination of the battery pack 50 with the tag antenna 91, and the loop antenna 42 communicates with the card reader antenna outside the mobile phone 1. Although another wireless communication is performed, the loop antenna 82 and the loop antenna 42 are electrically connected in series, so that the multi-function of the antenna can be achieved, and the number of terminals can be reduced by the common use of the terminals. It becomes possible.

  Incidentally, since the tag reader antenna 81 also faces the tag antenna 91, the laying range of the loop antenna 82 becomes smaller than the area of the battery surface 52. A battery surface 52 is present in front of the card antenna 41. That is, in this case, the antenna communication sensitivity of any of the loop antennas 42 and 82 is lowered by the battery surface 52.

  However, in this embodiment, the laying range of the tag RFID magnetic member 96 and the laying range of the card RFID magnetic member 46 are combined to cover the battery surface 52 for the first time, and the communicable direction of the loop antenna 82 and the loop It is possible to change the communicable direction of the antenna 42 and further prevent the antenna communication sensitivity from deteriorating.

More specifically, when the battery pack cover 22 is seen through the outer surface 17 (FIG. 7 (c)), if the entire battery surface 52 is covered only with the card RFID magnetic member 46, the magnetic flux is applied to the card RFID. Around the magnetic member 46, the RFID tag 90 becomes difficult to communicate.
On the other hand, if the RFID magnetic member 46 for cards is laid only between the loop antenna 42 and the battery surface 52 instead of between the loop antenna 82 and the battery surface 52 as in this embodiment, the wireless communication is obstructed. Even if the factors are close to each other, the card RFID magnetic member 46 first attracts the magnetic flux, and the magnetic flux penetrates between the outside of the mobile phone 1 and the loop antenna 42 described above.

Therefore, when viewed from the loop antenna 42, the card RFID magnetic member 46 can secure the communication direction to the outside of the mobile phone 1.
On the other hand, if the RFID magnetic member 96 for tags is laid between the loop antenna 92 and the battery surface 52, the RFID magnetic member 96 for tags attracts the magnetic flux even if the obstruction factor of wireless communication is close, and the loop antenna Magnetic flux also passes between 82 and the loop antenna 92.

Therefore, when viewed from the loop antenna 82, the tag RFID magnetic member 96 can ensure the communication direction to the inside of the mobile phone 1. Thereby, for example, only the battery pack 50 determined to be a genuine product can be used as a driving power source for the mobile phone 1, and the safety of the user can be ensured.
Furthermore, if the RFID magnetic member 46 for cards and the RFID magnetic member 96 for tags are used, in which the magnetic film is divided into two layers and an insulating film layer is sandwiched between them, in addition to improving the antenna communication sensitivity, a thin antenna can be obtained. It can be obtained and can meet the demand for thinning of the mobile phone 1.

In the embodiment shown in FIG. 11, the reader RFID magnetic member 86 is laid between the metal sheet 87 and the loop antenna 82.
Therefore, the metal sheet 87 does not become an obstacle to wireless communication, and the communicable direction of the loop antenna 82 can be secured. The metal sheet 87 can reliably prevent the communication content related to the authenticity determination of the battery pack 50 from leaking to the outside of the mobile phone 1.

  Furthermore, if the loop antenna 82 and the loop antenna 42 are arranged on the inner side and the outer side and connected in a row, the number of spiral turns can be reduced as compared with the case where each antenna is provided separately. The laying range of each antenna can also be reduced. Therefore, the mobile phone 1 having a multi-function space-saving antenna can be provided.

Furthermore, the loop antenna 82 and the loop antenna 42 connected in a row are formed on the same surface of the battery pack cover 22 (or the back cover 22A), and compared with the case where each antenna is provided on a different surface. , Making its manufacture easier.
Further, the loop antenna 82 and the loop antenna 42 can carry out communication for a wide range of applications such as traffic electronic money as non-contact wireless communication, in addition to authenticity determination of the battery pack 50.

The present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the claims.
For example, although the loop antenna 82 and the loop antenna 42 of each of the above embodiments are arranged on the same surface of the base film 45 to facilitate manufacture, the base film 45 is provided on the condition that they are connected in series. It is also possible to separately arrange the front surface and the back surface.

Further, the card antenna 41 may be used for credit in addition to the electronic traffic money described in the embodiment.
Further, each of the above embodiments has been described as an example embodied in the mobile phone 1. However, as long as ID management of the battery pack 50 is necessary in order to ensure the safety of the user, it is naturally applicable to mobile electronic devices such as PHS and PDA.

In the above embodiment, the metal case 51 is described as an example. However, the battery main body (battery constituent member) having the positive electrode member, the negative electrode member and the electrolyte may be housed in a resin case. .
Specifically, the resin case is formed in a cup shape having an opening, and when the battery body is disposed on the cup-shaped bottomed portion, the positive electrode member and the negative electrode member (battery component member) are formed. Is stored in a state exposed from the opening of the case.

And this opening is covered with the insulation seal which described information, such as a battery pack, and an electrode is hidden with an insulation seal.
For example, the RFID tag is affixed on the insulating seal and attached to the electrode via the insulating seal. This electrode causes a decrease in antenna communication sensitivity for the reader and the card.

As described above, even when the electrode of the battery body, not the case, becomes a communication hindrance factor, the laying range of the RFID magnetic member for tag and the laying range of the RFID magnetic member for card are combined to cover the electrode of the battery body. Hidden.
In any of these cases, as described above, there is an effect that the identification information of the battery pack can be reliably managed even in a minute space close to the metal member while achieving multi-function of the antenna.

1 Mobile phone (mobile terminal)
2 Telephone body (mobile terminal body)
22 Battery pack cover (lid member)
22a Cover outer surface (cover outer surface)
22b Cover inner surface (lid inner surface)
22A Back cover (lid member)
41 Card antenna 42 Loop antenna (Card antenna)
46 RFID magnetic member for cards (second magnetic body)
50 battery pack 51 case (battery component)
52 Battery surface (surface of battery component)
80 Reader / Writer 81 Tag Reader Antenna 82 Loop Antenna (Tag Reader Antenna)
86 RFID magnetic member for reader (third magnetic body)
87 Metal sheet (metal sheet)
90 RFID tag 91 Antenna for tag 92 Loop antenna (antenna part)
96 RFID magnetic member for tags (first magnetic body)

Claims (5)

A portable terminal that performs wireless communication between an RFID tag on the battery pack side and a reader / writer on the portable terminal body side,
Battery pack
A metal battery component;
A tag antenna for the RFID tag attached to the surface of the battery component;
While comprising a first magnetic body laid between the antenna portion of the tag antenna and the surface of the battery component,
The mobile device itself
A circuit board capable of determining the authenticity of the battery pack;
A lid member having a lid inner surface facing the mounted battery pack;
A tag reader antenna portion of the reader / writer attached to the lid member;
A card antenna unit that is electrically directly connected to the tag reader antenna unit and performs wireless communication different from the wireless communication;
Provided on the inner surface of the lid, between only the card antenna portion and the surface of the battery constituent member, in a region excluding the laying range of the first magnetic body on the surface of the battery constituent member A portable terminal with a battery pack authenticity determination function, comprising: a second magnetic body laid. A portable terminal with a battery pack authenticity determination function according to claim 1,
A metal sheet that is disposed on the opposite side of the tag reader antenna portion across the tag reader antenna portion and covers only the tag reader antenna portion;
A portable terminal with a battery pack authenticity determination function, further comprising a third magnetic body laid between the metal sheet and the tag reader antenna portion. A portable terminal with a battery pack authenticity determination function according to claim 1 or 2,
The tag reader antenna unit and the card antenna unit are electrically connected directly and wound spirally,
A portable terminal with a battery pack authenticity determination function, wherein the tag reader antenna section is arranged inside the card antenna section. A mobile terminal with a battery pack authenticity determination function according to any one of claims 1 to 3,
The portable terminal with a battery pack authenticity determining function, wherein the tag reader antenna unit and the card antenna unit are attached to an outer surface of the cover member exposed to the outside or an inner surface of the cover member. A mobile terminal with a battery pack authenticity determination function according to any one of claims 1 to 4,
The card antenna unit performs non-contact wireless communication with an external reader / writer, and is a portable terminal with a battery pack authenticity determination function.

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