JP2007294275A - Secondary battery package body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a secondary battery package body restraining cost increase at the time of sales by endowing a sales-use package body of a secondary battery with a function of charging the battery to keep it in a charged state. <P>SOLUTION: A charging pack 36 is attached in free detachment to a blister pack 21 packaging a secondary battery. The blister pack 36 supplies the blister pack 21 with charging power enough to compensate self discharge of the secondary battery by dint of a solar cell 31 or electromagnetic induction. The secondary battery is charged as it is displayed for sales, so that a user can purchase one already charged, while the charging pack 36 is removed and collected as the battery is sold, and this reuse restrains cost hike. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a secondary battery package suitable for selling a secondary battery in a charged state.

  Among secondary batteries, nickel metal hydride storage batteries and nickel cadmium storage batteries have a high self-discharge rate, and a decrease in dischargeable capacity is inevitable when the storage period and the sales period become long. In addition, although the lithium secondary battery has a small self-discharge rate, storage in a fully charged state is likely to cause deterioration of the battery, and is sold at a charge amount of 50% or less.

  Therefore, when the user purchases the secondary battery, it first takes time to charge the battery and then to load the required device. There has been a problem that a purchased battery such as a dry battery cannot be immediately loaded into a device and used. If the output voltage is close to the output voltage of the dry battery, such as a nickel metal hydride battery, and the dimensions are the same as the dry battery, compatibility with the dry battery can be obtained, and it is not disposable like the dry battery, and it can be used repeatedly. Can be obtained. For this purpose, the user is required to sell in a state where the dischargeable capacity is sufficient so that it can be used immediately without being charged after purchase.

  Nickel-metal hydride storage batteries have been developed that can be maintained at a dischargeable capacity of around 80% even after one year has passed since they were fully charged and shipped, but there is a problem that the capacity of the same size is reduced. Yes, it takes time and effort to manage the elapsed time from shipping to actual use.

  It is ideal to purchase a secondary battery that has sufficient dischargeable capacity when the user needs it. In reality, however, a secondary battery that can be used immediately is surely delivered to the user for the reasons described above. Is in a difficult state.

  To make it possible for users to purchase a secondary battery that has been charged and has sufficient dischargeable capacity, it is possible to charge and sell it at a sales base, but the secondary battery can be charged without destroying the package. In order to achieve this, a configuration for supplying charging power to the secondary battery in a non-contact manner is required. 2. Description of the Related Art An electromagnetic induction charging method that supplies charging power to a secondary battery incorporated in a device such as an electric shaver or an electric toothbrush by electromagnetic contact is widely known (see Patent Document 1). In this case, the device and the charger are provided with a power transmission configuration by electromagnetic induction.

In order to charge the secondary battery itself, it is necessary to electrically connect a charging circuit to the positive electrode and the negative electrode of the secondary battery, and an electromagnetic induction secondary coil is wound around the outer periphery of the secondary battery, and the electromagnetic induction secondary coil is A battery that is configured as a special secondary battery provided with a charging circuit that supplies an induced electromotive force as charging power for the secondary battery is known (see Patent Document 2 and Patent Document 3). The secondary battery provided with the charging structure by the electromagnetic coupling can be charged with the electric power by the electromagnetic induction by putting it into a dedicated charger provided with the electromagnetic induction primary coil.
JP-A-11-0669639 JP 2005-124324 A JP 2005-117748 A

  The configuration in which the secondary battery built into the device, such as the electric shaver shown as the prior art, is charged by electromagnetically coupling with the charger is the type and number of portable electronic devices that use the secondary battery as a power source. As the number increases, the scope of application is expected to increase for mobile phones and mobile computers. However, the secondary battery itself intended by the present invention is not sold in a state where it is charged in a state where it can be used immediately after purchase.

  In addition, the configuration provided with a charging function in the secondary battery itself shown as the prior art is not versatile and has a charging function because the secondary battery does not conform to the standard and is special. However, a decrease in volume as a secondary battery is unavoidable, resulting in a secondary battery having a small volumetric energy density. Even in the case of this special secondary battery, the object of the present invention is not fulfilled so that the secondary battery can be sold in a state where it can be used immediately after purchase.

  In addition, if the package for selling the secondary battery is provided with a function of charging the secondary battery, the cost is naturally increased, and although the convenience can be provided to the user, an extra expense is imposed.

  The purpose of the present invention is to sell a general-purpose general-purpose secondary battery that is charged in such a way that it can be loaded and used immediately after purchase. Another object is to provide a secondary battery package.

  The secondary battery packaging body according to the present invention for achieving the above object is provided with a connection terminal on the packaging body covering and packaging the secondary battery so as to be electrically connected to the secondary battery so as to be externally connectable. Charging means for supplying charging power to the secondary battery through the terminal is detachably connected to the package.

  According to the above configuration, the secondary battery is charged by the charging power output from the charging means connected to the secondary battery packaging body at the sales location of the secondary battery packaging body in which the secondary battery is coated and packaged for sale. . When the charging means is detachably attached to the package, it can be removed and reused at the time of sale, and wasteful cost increases can be suppressed.

  In the above configuration, the package is formed in a blister pack, and the surface of the connection terminal provided on the mount is covered with the mounting surface of the transparent cup to the mount, so that any metal object comes into contact with the connection terminal. It is possible to prevent a short circuit from occurring in the secondary battery.

  Moreover, if a charging means is comprised as a solar cell, it can charge a secondary battery with the electric power output from the solar cell which received irradiation of illumination light etc.

  In addition, the charging means is an electromagnetic induction secondary coil that electromagnetically couples with the electromagnetic induction primary coil of the magnetic field generating means disposed outside, and the electromotive force induced in the electromagnetic induction secondary coil is converted to a predetermined power to be supplied to the secondary battery. When configured with a charging power conversion circuit for conversion, an electromotive force is induced in the electromagnetic induction secondary coil by a magnetic field generated from the electromagnetic induction primary coil arranged close to the secondary battery package, and this is converted into charge power conversion. When converted into charging power by the circuit, the secondary battery can be charged.

  The charging means includes a receiving antenna that receives an electromagnetic wave output from an antenna of an electromagnetic wave oscillation device disposed outside, and a charging power conversion that converts an electromotive force induced in the receiving antenna into a predetermined power supplied to the secondary battery. When the electromotive force generated in the antenna that receives the electromagnetic wave output from the electromagnetic wave generating device arranged in the vicinity of the secondary battery package is converted into the charging power by the charging power conversion circuit, the secondary battery is charged. Electric power can be supplied.

  In addition, the connection between the charging power generation means and the package is preferably formed in a detachable structure with a dedicated jig, so that the charging power generation means is not unreasonably removed in the sales display state. Then, when the price is settled, if it is removed from the dedicated jig, the collection can be surely performed.

  In addition, the charging means separates the charge pack from the package at the time of purchase by the user by forming a charge power generation circuit using a solar cell or electromagnetic wave reception or an electromotive force generated by electromagnetic induction in a container. Can be easily constructed.

  The said charge pack can construct | assemble the structure which accommodated the charge pack in the transparent cup with the secondary battery, and was electrically connected in the transparent cup, when a package body was formed in the blister pack.

  According to the present invention, a secondary battery having a high self-discharge rate can be gradually charged at a storage location or a sales location to obtain a charge amount usable at the time of purchase by the user. Enables the use of dry batteries that can be used immediately after purchase. In addition, since the charging means can be attached and detached, it can be recovered and reused, and the charged secondary battery can be sold while suppressing the cost increase.

  Although this embodiment demonstrates the secondary battery package for selling the nickel hydride storage battery which is an example of a secondary battery, it cannot be overemphasized that other secondary batteries from which a specification, a packaging form, etc. differ can be constituted similarly. Yes.

  Nickel metal hydride storage batteries have a higher energy density than nickel cadmium storage batteries and do not use materials subject to chemical substance regulations in the EU (European Union). Since it is not necessary to provide a protection circuit for preventing charging and overdischarge, it is suitable as a general-purpose secondary battery. In addition, the output voltage (nominal voltage) is 1.2V, which is close to the output voltage of a dry cell, and has the same size and shape as the dry cell, so that compatibility with the dry cell can be obtained, and it can be used repeatedly by charging. It also has sex. In order to obtain such a use as a dry battery, it is required to solve the problem of a large self-discharge rate which is a characteristic of a nickel metal hydride storage battery. That is, it is desired that the device can be immediately loaded and used without being purchased and charged.

  In this embodiment, when a user purchases a nickel-metal hydride storage battery, the user can sell it in a charged state with sufficient dischargeable capacity at the time of purchase, rather than taking the trouble of charging the device after charging it as in the past. A secondary battery package is formed.

  FIG. 1 shows the structure of a secondary battery packaging body 1 according to the first embodiment. A charging pack (charging) is provided at one end of a blister pack 21 covering and packaging two AA-sized nickel-metal hydride storage batteries 5 and 5. Means) 36 is detachably connected.

  In the blister pack 21, terminal fittings 11, 12, and 13 that electrically connect two nickel metal hydride storage batteries 5 and 5 in series are mounted on the mount 6, and are connected to the positive electrodes of the nickel hydride storage batteries 5 and 5 that are connected in series. A positive electrode lead 24 drawn out from the terminal fitting 12 and a negative electrode lead 25 drawn out from the terminal fitting 11 connected to the negative electrode are formed on the mount 6. Two nickel metal hydride storage batteries 5 and 5 are attached to the terminal fittings 11, 12 and 13, and a transparent cup 14 is attached on the mount 6. The sticking surface of the transparent cup 14 to the mount 6 covers the positive electrode lead 24 and the negative electrode lead 25 and extends to the ends of the mount 6, and the positive electrode to be described later is formed on the respective ends of the positive electrode lead 24 and the negative electrode lead 25. A connection piece insertion portion 26 is formed by providing a space for accommodating the connection piece 28 and the negative electrode connection piece 29. With this configuration, it is possible to prevent a short circuit between the positive electrode lead 24 and the negative electrode lead 25 due to contact of some metal object.

  The charge pack 36 is constituted by a solar cell 31 in the present embodiment. The solar cell 31, the backflow prevention diode 32, the positive electrode connection piece 28, and the negative electrode connection piece 29 are attached to the substrate 33 for wiring connection, and the substrate 33 is accommodated in the cover case 35 provided with the transparent window 43. The light incident on the substrate 33 is secured, and the components on the substrate 33 are protected. The charging pack 36 is electrically connected to the blister pack 21 by inserting the positive electrode connection piece 28 and the negative electrode connection piece 29 into connection piece insertion portions 26, 26 provided at the end of the blister pack 21. The charging pack 36 is connected.

  The connection between the blister pack 21 and the charge pack 36 is locked by the connection lock 30 so that the connection cannot be released. When the user purchases and pays for the price, the connection lock 30 is unlocked by a dedicated jig and charged from the blister pack 21. It is desirable to remove the pack. The charge pack 36 removed from the blister pack 21 is collected at the sales base and can be reused, thereby suppressing an increase in cost due to the construction of a package with a charging function. Further, by locking the connection between the blister pack 21 and the charge pack 36, it is possible to prevent the blister pack 21 and the charge pack 36 from being separated due to theft or mischief.

  FIG. 2 is a circuit diagram showing a charging circuit configuration of the secondary battery package 1 having the above-described configuration. Since electric power is generated when the indoor illumination light at the sales base enters the solar battery 31, the number of elements of the solar battery 31 is generated so that a voltage is generated so that the generated power becomes the charging power of the nickel-metal hydride storage batteries 5 and 5. Is set. Unlike ordinary charging, it is sufficient to carry out charging to a degree that compensates for the self-discharge of the nickel metal hydride storage batteries 5 and 5 gradually with a minute charging current. Here, since the nickel metal hydride storage batteries 5 and 5 are connected in series, the charging voltage output from the solar battery 31 may be such that a small amount of current flows in the nickel metal hydride storage batteries 5 and 5, and the voltage increases due to charging. When the voltage between the positive and negative electrodes of the nickel hydride storage batteries 5 and 5 becomes the same as the charging voltage, charging is stopped.

  Depending on the display location of the secondary battery packaging 1 at the sales base, it may be assumed that sufficient illumination light is not irradiated to all of the displayed charge packs 36. In such a case, the display is located above the display location. It is desirable to provide a light irradiation means dedicated to charging. As the light irradiation means, those that do not occupy a sales space such as a small fluorescent lamp, LED, and EL are preferable.

  FIG. 3 shows the charging pack 37 constituting the secondary battery packaging body 2 according to the second embodiment, and the blister pack 21 connecting the same is the same as that of the first embodiment. Description is omitted. The charging method in the present embodiment is configured to receive the electromagnetic wave output from the antenna of the electromagnetic wave transmitter disposed outside and obtain charging power for the two nickel metal hydride storage batteries 5 and 5.

  The charging pack 37 includes a charging circuit as shown in FIG. 4 formed on a substrate 38. An antenna coil (receiving antenna) 39 is formed in a spiral shape on the back surface of the substrate 38, and a capacitor is connected in parallel to the antenna coil 39. 40 is connected to form a resonance circuit, and the electromotive force induced by resonating with the electromagnetic wave received by the antenna coil 39 is rectified by the rectifier diode 41 to obtain charging power. A positive electrode connection piece 28 and a negative electrode connection piece 29 are attached to the end of the substrate 38, and the generated charging power is supplied to the blister pack 21 by connecting to the positive electrode lead 24 and the negative electrode lead 25 provided in the blister pack 21, respectively. Supply.

  The substrate 38 is preferably formed as a printed wiring board in which an antenna coil 39 is formed on the back surface, and a connection line and a soldering land are formed on the surface, and the capacitor 40 and the rectifier diode 41 are soldered. A charging circuit can be easily configured by fastening the positive electrode connection piece 28 and the negative electrode connection piece 29.

  The substrate 33 is formed in the charging pack 37 by being accommodated in the cover case 42 with the positive electrode connection piece 28 and the negative electrode connection piece 29 exposed outside. In the charging pack 37, the connecting piece insertion portion 26 in which the positive electrode connecting piece 28 and the negative electrode connecting piece 29 are provided at the end of the blister pack 21 by inserting the blister pack 21 into an opening that is thinly opened at one end of the cover case 42. , 26 and electrical connection is made, and the blister pack 21 and the charge pack 36 are connected. The connection between the blister pack 21 and the charge pack 36 is locked so that the connection cannot be released by the connection lock 30 as in the previous configuration, and the user purchases and connects with the connection tool 34 using a dedicated jig at the time of payment. It is desirable that the charging pack be removed from the blister pack 21 by releasing.

  Fig.5 (a) shows the structure of the secondary battery packaging body 3 which concerns on 3rd Embodiment, and is comprised so that the charging power with respect to the two nickel metal hydride storage batteries 5 and 5 may be obtained by electromagnetic induction. . A charging pack 22 that generates charging power by electromagnetic induction is detachably connected to one end of a mount 6 constituting a blister pack 21 in which two nickel metal hydride storage batteries 5 and 5 are packaged.

  The blister pack 21 is formed in the same manner as in the previous embodiment as shown in FIG.

  5B, the charging pack 22 accommodates the electromagnetic induction secondary coil 7, the capacitor 10, and the rectifier diode 9 in a thin cover case 27 by resin molding, and these are connected to the positive electrode connecting piece. 28 and the negative electrode connection piece 29 are connected to form a charging circuit as shown in FIG. In this configuration, the electromagnetic induction secondary coil 7 is a cylindrically wound one, but may be a spiral structure.

  When the charging pack 22 is closed, when the cover case 27 having a folded structure is closed, one end side is opened thinly, and the positive electrode connection piece 28 and the negative electrode connection piece 29 are exposed in the opening portion. When the connection piece 29 is inserted into the connection piece insertion portion 26 of the blister pack 21 and the end side of the blister pack 21 is inserted into the opening, the blister pack 21 and the charging pack 22 are connected simultaneously and electrically connected. The As in the previous configuration, the connection between the blister pack 21 and the charging pack 22 is locked so that the connection cannot be released by the connection lock 30, and the user purchases the connection and releases the connection with a dedicated jig at the time of payment. It is desirable to remove the charging pack from the pack 21.

  As shown in FIG. 6, the secondary battery packaging body 3 is manufactured in a storage place where a plurality of the secondary battery packaging bodies 3 are manufactured and packed in a cardboard box and shipped to the sales base, or in a sales place where the secondary sales are displayed and sold at the sales base. Charging power is obtained from the electromotive force generated in the electromagnetic induction secondary coil 7 that is electromagnetically coupled to the magnetic field generated from the electromagnetic induction primary coil 20 provided in the configured non-contact power transmission device 15, and the nickel metal hydride storage batteries 5 and 5 are charged. Supply power.

  In FIG. 6, the non-contact power transmission device 15 includes an oscillation circuit 17 that operates by DC power obtained by converting AC power by a rectifying and smoothing circuit 16. When the non-contact power transmission device 15 is activated and the oscillation circuit 17 oscillates at a required frequency, a magnetic field is generated from the electromagnetic induction primary coil 20 constituting the oscillation circuit 17. When the secondary battery package 1 is disposed in the generated magnetic field, an electromotive force is induced in the electromagnetic induction secondary coil 7 by electromagnetic induction caused by the magnetic field. A resonance circuit is configured by the electromagnetic induction secondary coil 7 and the capacitor 10 connected in parallel thereto, and the alternating current generated by the resonance is rectified by the rectifier diode 9 and supplied to the nickel metal hydride storage batteries 5 and 5 as charging power.

  The charging in this configuration is different from the general charging, and it is sufficient to carry out the charging to compensate for the self-discharge of the nickel metal hydride storage batteries 5 and 5 with a small charging current. Here, since the nickel hydride storage batteries 5 and 5 are connected in series, the charging voltage output from the rectifier diode 9 is such that a small amount of current flows in the nickel hydride storage batteries 5 and 5, for example, 1.3 to 1 The charge is stopped when the voltage between the positive electrode and the negative electrode of the nickel-metal hydride batteries 5 and 5 whose voltage has increased due to charging becomes equal to the charging voltage. The rectifier diode 9 has a role of preventing a backflow that prevents a current from flowing in the discharge direction from the nickel hydride storage batteries 5 and 5 while flowing a charge current in the charge direction to the nickel hydride storage batteries 5 and 5.

  FIG. 7A shows the configuration of the secondary battery package 4 according to the fourth embodiment. In the transparent cup 14 constituting the blister pack, two nickel-metal hydride storage batteries 5 and 5 and the charge pack 46 are shown. And is housed. The charge pack 46 can be configured as a charging means using any one of the solar cell, electromagnetic wave, and electromagnetic induction in the embodiment described above.

  The charging pack 46 accommodates the constituent elements of the charging means in the container, and the connection pieces are externally exposed at both ends of the container. The distance between the connection pieces provided at both ends is the height of the nickel hydrogen storage batteries 5 and 5. It matches the dimensions. When the charging pack 46 and the two nickel-metal hydride storage batteries 5 and 5 are stored in the connection holder 45 configured as shown in FIG. 7C, the connection plates 47 provided on both inner side surfaces of the connection holder 45 mutually connect each other. Electrical connection is made. Here, the two nickel metal hydride storage batteries 5, 5 are connected in parallel and connected to the charge pack 46.

  As shown in the cross-sectional view of FIG. 7B, the side surface of the transparent cup 14 is formed with a drawing taper necessary for molding, so that a vertical contact surface with respect to the nickel metal hydride storage batteries 5 and 5 and the charge pack 46 is not formed. . Therefore, by pushing the connection holder 45 into the transparent cup 14, the folded pieces 45 a provided on both sides of the connection holder 45 come into contact with the inner surface of the transparent cup 14 where the taper is formed and the connection plate of the connection holder 45 is connected. A state is obtained in which the sticking surfaces of 47 are pressed inside each other, and the connection plate 47 is in pressure contact with both the positive and negative electrodes of the accommodated nickel-metal hydride storage batteries 5 and 5 and the both end connection pieces of the charge pack 46. By forming a connection protrusion 47a at the contact position of the connection plate 47 with the nickel metal hydride storage batteries 5 and 5 and the charge pack 46, a more stable contact connection state can be obtained.

  In the form shown in the figure, the charging pack 46 is located at the lowermost part of the secondary battery packaging body 4. Therefore, if the solar battery 31 is arranged on the lower surface of the secondary battery packaging body 4, If a light source dedicated to power generation is arranged below, efficient charging power can be performed. Further, when the electromagnetic induction primary coil or the electromagnetic wave transmitting antenna is arranged below the sales display place of the secondary battery package 4, the electromagnetic induction secondary coil 7 or the antenna coil 39 of the charging pack 46 is arranged. Power transmission can be performed from a close position.

  The accommodation position of the charging pack 47 in the transparent cup 14 can be arbitrarily set according to the arrangement position of the electromagnetic induction primary coil 20. For example, when the charging pack 46 is configured to generate charging power from a solar cell, the charging pack 46 is accommodated above the transparent cup 14 and a solar cell is disposed on the upper surface thereof. Power generation by light can be used.

  Since the charge pack 46 in this configuration is accommodated in the transparent cup 14 so as to be separable from the nickel metal hydride storage batteries 5, 5, the charge pack 46 is pushed out from the transparent cup 14 by opening the corresponding part of the mount 6 corresponding to the charge pack 46. And can be collected and reused at the time of purchase by the user. For example, as shown in FIG. 7, an extraction door 52 is provided in the charging holder 46 holding portion of the connection holder 45 so as to be openable and closable, and as shown in FIG. 8, an extraction window 51 formed on the back surface of the mount 6 has a notch 52 a. When the jig is inserted and the takeout door 52 is opened, the charging cup 46 can be pushed out from the transparent cup 14 and taken out from the takeout window 51 to the outside.

  As described above, according to the present invention, since the charging means is detachably connected to the package in which the secondary battery is covered and packaged, when the charging means is removed from the package at the time of purchase by the user, the charging means is A rechargeable secondary battery can be sold while being able to be reused and suppressing an increase in cost due to the provision of charging means. Therefore, a user who has purchased a secondary battery can immediately use it by loading it into a device without performing a charging operation, and it is possible to use a secondary battery that can be used repeatedly as a dry battery. Can be realized.

(A) of the secondary battery packaging body which concerns on 1st Embodiment, (b) is a charge pack, (c) is a perspective view which shows the structure of a blister pack. The circuit diagram which shows the solar cell charging circuit in a structure same as the above. The perspective view which shows the structure of the charge pack of the secondary battery packaging body which concerns on 2nd Embodiment. The circuit diagram which shows the electromagnetic wave receiving circuit in a structure same as the above. (A) of the secondary battery packaging body which concerns on 3rd Embodiment, (b) is a charge pack, (c) is a perspective view which shows each structure of a blister pack. The circuit diagram which shows the electromagnetic induction circuit in a structure same as the above. (A) of the secondary battery packaging body which concerns on 4th Embodiment is a perspective view which shows the whole structure, (b) is sectional drawing, (c) is a perspective view of a connection holder. The perspective view which shows the example of the charge pack taking-out structure in a structure same as the above.

Explanation of symbols

1, 2, 3, 4 Secondary battery packaging 5 Nickel metal hydride storage battery (secondary battery)
6 Mount 7 Electromagnetic induction secondary coil 9 Rectifier diode 10 Capacitor 11, 12, 13 Terminal fitting 14 Transparent cup 20 Electromagnetic induction primary coil 21 Blister pack 22, 36, 37, 46 Charge pack 24 Positive electrode lead 25 Negative electrode lead 28 Positive electrode connection piece 29 Negative connection piece 30 Connection lock

Claims (8)

  A packaging body for covering and packaging the secondary battery is provided with a connection terminal that is electrically connected to the secondary battery so as to be externally connectable, and charging means for supplying charging power to the secondary battery through the connection terminal is provided to the packaging body. A secondary battery package characterized by being detachably connected.   The secondary battery packaging body according to claim 1, wherein the packaging body is formed in a blister pack, and a surface of a connection terminal provided on the mount is covered with a mounting surface of the transparent cup to the mount.   The secondary battery package according to claim 1 or 2, wherein the charging means is a solar battery.   The charging means converts the electromagnetic induction secondary coil electromagnetically coupled with the electromagnetic induction primary coil of the magnetic field generating means disposed outside, and converts the electromotive force induced in the electromagnetic induction secondary coil into predetermined power supplied to the secondary battery. The secondary battery packaging body according to claim 1 or 2, comprising a charging power conversion circuit.   The charging means includes a receiving antenna that receives an electromagnetic wave output from an antenna of an electromagnetic wave oscillation device disposed outside, a charging power conversion circuit that converts an electromotive force induced in the receiving antenna into a predetermined power supplied to the secondary battery, and The secondary battery packaging body according to claim 1 or 2, comprising:   The secondary battery packaging body according to any one of claims 1 to 5, wherein the connection between the charging power generation means and the packaging body is formed in a detachable structure using a dedicated jig.   The secondary battery package according to claim 1, wherein the charging means is formed in a charging pack in which a charging power generation circuit using an electromotive force generated by a solar cell or electromagnetic wave reception or electromagnetic induction is accommodated in a container.   The secondary battery packaging body according to claim 7, wherein the packaging body is formed in a blister pack, the charging pack is housed in a transparent cup together with the secondary battery, and electrical connection is made in the transparent cup.

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