JP2001093581A - Knitted battery and battery wear with same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow supply of stand-by power during carrying or to allow charging of an interior secondary battery. SOLUTION: Linear negative electrode material 11 and positive electrode material 14 each formed by applying electrode active substance 13 and 16 on collectors 12 and 15 are deposited upon each other while interposing a solid polymer 17, and sealed by means of a sheath 18, thereby forming a flexible linear unit polymer secondary battery 10. A plurality of unit polymer secondary batteries 10 are knitted using as a fabric material to form a flexible, fabric-like knitted battery 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a braided battery formed by using a unitary polymer secondary battery body formed in a linear shape as a fiber material and knitting it as a fabric, and a battery wear having the braided battery.

[0002]

2. Description of the Related Art Generally, a secondary battery that can be repeatedly charged together with a commercial power supply is used as a power supply for various portable electronic devices and the like. By the way, portable electronic devices, etc.
Along with the reduction in thickness and weight, multi-functionality or long-term use has been attempted, and for this reason, a secondary battery with high output, high capacity, small size and thinness and high safety is required. Conventionally, lead-acid batteries and nickel-cadmium storage batteries have been used as secondary batteries, but the development of smaller, lighter, and more secure lithium-ion secondary batteries has led to the development of portable lithium-ion batteries. It is designed to be mounted on electronic devices such as portable electronic devices.

In a lithium ion secondary battery, a negative electrode is formed of a negative electrode active material made of a carbon-based material capable of doping / dedoping lithium, and a transition metal containing lithium such as lithium cobalt oxide or lithium nickel oxide is used. A positive electrode is composed of a positive electrode active material composed of an oxide. In a lithium ion secondary battery, a negative electrode and a positive electrode are overlapped with a separator interposed therebetween to form a power generator. The power generator is loaded into a battery can, filled with an electrolyte, and sealed with a battery lid.

[0004] Lithium ion secondary batteries have various features such as being clean, having a high energy density, being excellent in cycle characteristics and safety, and being excellent in low temperature characteristics, load characteristics, and rapid charging characteristics. Although such a lithium ion secondary battery is used, the thickness of the battery can is limited to about 4 mm due to the presence of a battery can, and it is difficult to produce a free shape.

As a new secondary battery, a polymer secondary battery using a solid electrolyte instead of a conventional electrolytic solution has been receiving attention. The polymer secondary battery eliminates the need for a battery can because there is no liquid leakage, and encloses the power generator with an exterior material made of metal foil such as aluminum foil and a plastic film such as nylon, polyethylene, polypropylene, and polyethylene terephthalate. It becomes. Therefore, the polymer secondary battery has a feature that its thickness is configured to be 1 mm or less and that it can be formed into a free shape.

[0006]

In a portable electronic device or the like, a secondary battery mounted on a portable device is used as a power source for a long time, but the capacity of the secondary battery is insufficient during use. Things often happened. For this reason, the user purchases a spare battery pack and carries it around, but it is troublesome to purchase it and often forgets to bring it because it is heavy and bulky. There was such a problem.

[0007] In a portable electronic device or the like, a secondary battery is charged via a charger at night or the like, and this operation is often forgotten. In addition, in a portable electronic device or the like, since the secondary battery cannot be carried and used while the secondary battery is being charged, the secondary battery is often forgotten to be charged or insufficiently charged.

On the other hand, portable electronic devices and the like which are usually carried and used include information processing devices such as personal computers, and AV devices such as camcorders, tapes and discs for reproduction only.
There are various types such as devices and mobile phones.
Therefore, the user must carry a dedicated backup power supply pack and carry out a charging operation for each of these portable electronic devices and the like to cope with the above-described problems, but it is impossible to perform the operation at all. As a result, the capacity shortage of the secondary battery frequently occurred.

Therefore, the present invention provides a portable electronic device or the like that can supply power as a backup power source or charge a built-in secondary battery even when it is carried, so that a situation such as running out of battery can be achieved. The present invention has been proposed for the purpose of providing a braided battery whose generation is suppressed and a battery ware including the braided battery.

[0010]

A knitted battery according to the present invention, which achieves the above object, comprises a solid negative electrode material and a positive electrode material obtained by applying a polar active material to a current collector. A flexible linear unit polymer secondary battery body is formed by superimposing and sealing with an exterior material, and by knitting the unit polymer secondary battery body as a fiber material, the whole becomes flexible. It is comprised in the cloth shape which has.

According to the braided battery according to the present invention configured as described above, the portable electronic device can be used as a portable case or back by using it as a lining for clothes, a portable electronic device, or the like. It supplies power as a standby power supply to devices and the like and acts as a charging power supply for a built-in secondary battery. The braided battery is warmed by the user's body temperature when used for clothes,
The low-temperature characteristics are improved, and power is supplied to portable electronic devices and the like in a stable state.

A battery ware provided with a braided battery according to the present invention that achieves the above-mentioned object comprises a linear negative electrode material and a positive electrode material obtained by applying a polar active material to a current collector by a solid polymer electrolyte. A flexible unit polymer secondary battery body having flexibility by superimposing via a sealing material with an exterior material, and using the unit polymer secondary battery body as a fibrous material, the fabric having flexibility as a whole. And a knitted battery which is knitted in a pocket, is provided on a lining or the like, and can be connected to an electronic device or the like stored in a pocket or the like.

According to the battery ware provided with the braided battery according to the present invention configured as described above, power is supplied to a portable electronic device or the like as a standby power supply when the capacity of the secondary battery is insufficient. Since the battery pack is used as a charging power source for the secondary battery, it is not necessary to carry a spare power supply pack corresponding to the portable electronic device, so that it can be used for a long time. Battery ware with a built-in battery is easy to carry, even if a large number of portable electronic devices are carried, by storing them in pockets, eliminating the need for a dedicated carrying case and improving storage. To be achieved. The battery ware having a braided battery is a state in which the braided battery is warmed by the user's body temperature, thereby improving low-temperature characteristics and providing a stable power supply to portable electronic devices and the like. Supply.

[0014]

Embodiments of the present invention will be described below in detail with reference to the drawings. The garment shown in FIG. 1 as an embodiment is a vest 1 in which a braided battery 2 (to be described in detail later) is sewn on a lining, and an appropriate portable electronic device 3 such as a disc playback machine or a mobile phone is used. It has a plurality of pockets 4 sufficient for storage. The vest 1 has an appropriate connector 5 omitting details in each pocket 4.
Are provided, and the portable electronic device 3 and the braided battery 2 housed in the pocket 4 via these connectors 5 are provided.
And can be connected.

Therefore, the braided battery 2 enables power to be supplied to the portable electronic device 3 through the connector 5, and constitutes a standby power supply when the electric capacity of the built-in secondary battery is insufficient. I do. The braided battery 2 constitutes a charging power source for charging the built-in secondary battery of the portable electronic device 3. On the other hand, the braided battery 2
Although not shown, charging is performed by connecting a commercial power supply to the connector 5.

The braided battery 2 is formed by knitting a plurality of linear unit polymer secondary battery bodies 10 described later in detail as a fiber material into a fabric as a whole. Although the details are omitted, the woven type battery 2 is detachably provided on the lining of the vest 1 via a fastener, a hook, or the like, and is sewn on the back side. Although the braided battery 2 is provided on the chest of the vest 1 shown in FIG. 1, it goes without saying that it may be provided on the back or both. The braided battery 2 may be provided not only on the vest 1 but also on a jacket or coat.

As shown in FIG. 2, the unit polymer secondary battery 10 is formed by applying a negative electrode active material mixture on one main surface of a negative electrode current collector 12 to form a negative electrode active material layer 13. A negative electrode material 11 and a positive electrode material 1 formed by forming a positive electrode active material layer 16 by applying a positive electrode active material mixture on one main surface of a positive electrode current collector 15
4 are laminated via a solid polymer electrolyte 17 and sealed with an exterior material 18 to form a lithium ion secondary battery. For the negative electrode current collector 12, for example, a copper foil cut into a band shape and having a thickness of about several μm to several tens μm is used. For the positive electrode current collector 15, for example, an aluminum foil cut into a band and having a thickness of about several μm to several tens μm is used.

As the negative electrode active material mixture, a material capable of doping and undoping lithium ions as the negative electrode active material, for example, a carbon material such as graphite, non-graphitizable carbon or graphitizable carbon is used. The negative electrode active material mixture is prepared by adding PYdF (polyvinylidene fluoride) as a binder and NMP (n-methylpyrrolidone) as a solvent to these carbon materials to form a slurry, and forming the negative electrode current collector 12 by a doctor blade method or the like. Uniformly applied on main surface. The negative electrode active material mixture is subjected to high temperature drying in a far infrared
The MP is skipped, and a pressure treatment by a roll press is performed to increase the density, and a negative electrode active material layer 13 is formed on the main surface of the negative electrode current collector 12. As the negative electrode active material, a polymer material such as polyacetylene or polypyrrole or an oxide such as SnO ₂ is used in addition to the carbon material.

The positive electrode active material mixture is, for example, TiS ₂ , Mo
Lithium-free metal sulfides or oxides such as S ₂ , NbSe ₂ , V ₂ O ₅ , or Li _x MO ₂ (where M represents one or more transition metals. _X depends on the charge / discharge state of the battery. In contrast, a lithium composite oxide or the like mainly containing 0.05 to 1.10 is used. Transition metal M
Is, for example, Co (cobalt), Ni (nickel), Mn
(Manganese), specifically, LiCoO ₂ , L
iNiO ₂ , LiNi _y Co _1-y O ₂ (0 <y <1), Li
Mn ₂ O ₄ is used. These lithium composite oxides
It is a substance that can generate high voltage and is excellent in energy density. The positive electrode active material may be a mixture of a plurality of these materials.

The positive electrode active material mixture is obtained by mixing PYdF as a binder and N
The slurry is formed by adding MP, and the slurry is uniformly applied on the main surface of the positive electrode current collector 15 by a doctor blade method or the like. The positive electrode active material mixture is subjected to a high-temperature drying treatment in a far-infrared furnace to blow off NMP, and further subjected to a pressure treatment by a roll press to achieve a high density, thereby forming a mixture on the main surface of the positive electrode current collector 15. Is formed.

The solid polymer electrolyte 17 is obtained by mixing a polymer material, an electrolytic solution, and an electrolyte salt to form a gelled electrolyte into a polymer. The polymer material has a property of being compatible with the electrolytic solution, and includes a silicone gel, an acrylic gel, an acrylonitrile gel, a polyphosphazene-modified polymer,
Polyethylene oxide, polypropylene oxide,
And their composite polymers, crosslinked polymers, modified polymers, etc., or fluorine-based polymers such as poly (vinylidene fluoride), poly (vinylidene fluoride- _co -tetrafluorosafluoropropylene), poly (vinylidene fluoride- _co- Various polymer materials such as trifluoroethylene) and mixtures thereof are used.

The electrolytic solution component can disperse the above-mentioned polymer material, and as the aprotic solvent, for example, ethylene carbonate (EC), propylene carbonate (PC), butylene carbonate (BC) or the like is used. As the electrolyte salt, one that is compatible with the solvent is used, and a combination of a cation and an anion is used. As the cation, an alkali metal or an alkaline earth metal is used. Anions include Cl ⁻ , Br ⁻ , I ⁻ , SCN ⁻ , ClO ₄ ⁻ , B
F ₄ ⁻ , PF ₆ ⁻ , CF ₃ SO ₃ ^{− and the} like are used. As the electrolyte salt, specifically, lithium hexafluorophosphate or lithium tetrafluoroborate is used at a concentration that can be dissolved in the electrolytic solution.

The unit polymer secondary battery body 10 includes the above-described negative electrode material 11, positive electrode material 14 and solid polymer electrolyte 17.
And a sealant 1 at both ends as shown in FIG.
9 is sealed with an exterior body 18 in a state of being filled.
The exterior body 18 has a certain degree of mechanical strength and flexibility while maintaining electrical insulation of the interior article. For example, nylon, polyethylene,
A polymer film such as polypropylene or polyethylene terephthalate is used, and a laminate film in which a metal foil and a plastic film are joined together is also used.

In the unit polymer secondary battery 10, as shown in FIG. 1, one end 12 a of the negative electrode current collector 12 is provided with a sealant 19 a.
And the other end 15a of the positive electrode current collector 15 is protruded and exposed from one end 18a of the exterior material 18 through the sealant 19.
b, it is projected and exposed from the other end portion 18b of the exterior material 18 via each. That is, the unit polymer secondary battery body 1
In the case of No. 0, the end 18a of the outer package 18 on the positive electrode side is thermally fused to the one end 12a of the negative electrode current collector 12 through the sealant 19a such that a part thereof is exposed to the outside. Is done. In the negative electrode current collector 12, a negative electrode current collection tab 20 made of, for example, a nickel piece is joined to the exposed end portion 12a. In the unit polymer secondary battery body 10, the end 18 b of the outer package 18 on the negative electrode side is connected to the one end 15 of the positive electrode current collector 15.
A is heat-sealed via the sealant 19b so that a part of the part a is exposed to the outside. The positive electrode current collector 15 includes
A positive electrode current collecting tab 21 made of, for example, an aluminum piece is joined to the exposed end portion 15a.

As described above, the unit polymer secondary battery body 10 has the negative electrode current collector tab 20 joined to one main surface of one end portion 12a of the negative electrode current collector 12 and the other main surface on the opposite side. Although the positive electrode current collecting tab 21 is joined to one end 15a of the positive electrode current collector 15 on the surface side, the present invention is not limited to this configuration. The unit polymer secondary battery body 10 pulls out the negative electrode current collector 12 and the positive electrode current collector 15 from the outer package 18 while maintaining insulation therebetween, and forms a negative electrode current collector tab 20 on each surface. Or you may make it join with the positive electrode current collection tab 21. Unit polymer secondary battery 1
No. 0 is a double-sided terminal type in which a negative electrode current collecting tab 20 and a positive electrode current collecting tab 21 are formed on the front and back surfaces at both ends by adopting such a configuration.

A large number of unit polymer secondary battery bodies 10 constructed as described above are prepared, and they are arranged as a fiber material in a matrix as shown in FIG. Thus, the braided battery 2 is formed. Each unit polymer secondary battery body 10 has the same length, and the negative electrode current collecting tab 20 and the positive electrode current collecting tab 21 are positioned and woven on the same side.

In the braided battery 2, since each unit polymer secondary battery body 10 has a flexible band shape,
The whole has a flexible sheet shape. The braided battery 2 is connected to the negative current collecting tab 20 of each unit polymer secondary battery body 10 along two adjacent side edges of one corner.
Are exposed and arranged, and the positive electrode current collecting tabs 21 of each unit polymer secondary battery body 10 are exposed and arranged along two adjacent side edges of the opposing corners. The braided battery 2 is connected to each negative electrode current collecting tab 20.
Are electrically and integrally connected to each other by a negative electrode terminal member 22, and the positive electrode current collecting tab 21 is electrically and integrally connected to each other by a positive electrode terminal member 23.

The braided battery 2 may be used not only alone but also in combination of a plurality of batteries. The braided battery 2 includes a plurality of negative electrode current collecting tabs 20 and a plurality of positive electrode current collecting tabs 2 facing each other.
1 are connected to each other, whereby a parallel specification is obtained. The braided battery 2 has a serial specification by superposing a plurality of sheets and connecting the respective negative electrode current collecting tabs 20 and respective positive electrode current collecting tabs 21 to each other. Therefore, the braided battery 2 constitutes a battery having a predetermined electric capacity by appropriately combining a plurality of batteries. In addition, the braided battery 2 can be configured into a parallel specification and a series specification by changing the combination state by 90 ° by using a double-sided terminal type as described above.

The braided battery 2 is sewn as a lining on the inner surface of the vest 1 after a plurality of the batteries are combined to have an appropriate size and shape and have a predetermined electric capacity as described above. Although the details of the woven battery 2 are omitted, the negative electrode terminal member 22 and the positive electrode terminal member 23 are connected to the connector 5. The braided battery 2 constitutes a backup power source for the built-in secondary battery and a charging power source for charging the portable electronic device 3 housed in the vest 1 as described above. The braided battery 2 is charged by being connected to a commercial power supply or the like via the connector 5.

When the vest 1 is worn on the user, the braided battery 2 is heated by its body temperature, so that the low-temperature characteristics of each unit polymer secondary battery 10 constituting the vest 1 can be improved. . Therefore, the braided battery 2 forms a standby power supply or a charging power supply with stable performance for the portable electronic device 3 housed in the vest 1. Since the braided battery 2 can be formed on the entire inner surface of the vest 1, it is possible to increase the capacity. The best 1 is to carry the portable electronic device 3 in the pocket 4 without getting in the way.
An unconventional battery device is configured.

The braided battery 2 has a structure in which a large number of unit polymer secondary battery bodies 10 are braided in a lattice as described above, but the present invention is not limited to such a structure. The braided battery 30 shown in FIG. 4 as the second embodiment of the present invention includes a pair of elongated unit polymer secondary battery bodies 31a and 31b, and these unit polymer secondary battery bodies 31a , 31b, and each piece is alternately woven in a state of being orthogonal to each other.

Unit polymer secondary batteries 31a, 31b
Since it has a flexible band shape, it constitutes a sheet-shaped braided battery 30 that is entirely flexible. In the braided battery 30, each unit polymer secondary battery body 31a, 31b has a negative electrode current collecting tab 20 on one end side.
Is formed and a positive electrode current collecting tab 21 is formed on the other end side. The negative electrode current collecting tabs 20 are connected by a negative electrode terminal member (not shown), and the positive electrode current collecting tabs 21 are connected by a positive electrode terminal member (not shown). Do it. In the braided battery 30, the negative electrode terminal member and the positive electrode terminal member are connected to the connector 5.

In the braided battery 30,
By connecting a plurality of negative electrode current collecting tabs 20 and positive electrode current collecting tabs 21 facing each other and arranging each other, a parallel specification is achieved. In addition, the braided battery 30 has a series specification by superimposing a plurality of sheets and connecting the respective negative electrode current collecting tabs 20 and respective positive electrode current collecting tabs 21 to each other. Therefore, the braided battery 30
Constitutes a battery having a predetermined electric capacity by appropriately combining a plurality of sheets. In addition, the braided battery 30 can be configured into a parallel specification and a series specification by changing the combination state by 90 ° by using a double-sided terminal type as described above.

Although the woven battery 30 has the trouble of folding the unitary polymer secondary battery bodies 31a and 31b, the man-hours for mounting the unit are reduced by reducing the number of the negative electrode current collecting tabs 20 and the positive electrode current collecting tabs 21. And the number of parts can be reduced. In addition, each unit polymer secondary battery body 31a, 31b
May of course be configured by connecting a plurality of unit polymer secondary battery bodies in series.

A braided battery 40 shown in FIG. 5 as a third embodiment of the present invention has a large number of unit polymer secondary battery bodies 41 arranged in a matrix as a fiber material and alternately in a lattice form. The configuration that can be woven and finished in a fabric shape is the same as that of the woven battery 2.
It is characterized by a configuration using a cord-shaped unit polymer secondary battery body 41. As described above, the unit polymer secondary battery body 10 is formed in a belt shape by stacking the strip-shaped negative electrode material 11, the cathode material 14, and the solid polymer electrolyte 17, and sealing these with the exterior material 18. .

Although not shown, the unit polymer secondary battery body 41 is formed, for example, by winding a solid polymer electrolyte and a positive electrode material around a negative electrode material formed in a linear shape as a core material. Seal it. The unit polymer secondary battery body 41 electrically insulates the negative electrode current collector tab provided on the negative electrode current collector of the negative electrode material and the positive electrode current collector tab provided on the positive electrode current collector of the positive electrode material from both ends of the exterior material. Is pulled out in a coaxial state in a state in which the connection terminals are held.

In the unit polymer secondary battery body 41, the positive electrode current collecting tab is exposed to the outermost periphery as it is, and this constitutes the positive electrode terminal 43. The unit polymer secondary battery body 41 forms the negative electrode terminal 42 by separating the positive electrode current collecting tab and the solid polymer electrolyte to expose the negative electrode current collecting tab of the core material. The unit polymer secondary battery 4
For example, 1 may be configured such that a solid polymer electrolyte and a negative electrode material are wound around the positive electrode material as a core material, and then the whole is sealed with an exterior material.

A large number of unit polymer secondary battery bodies 41 constructed as described above are prepared, and these are arranged in a matrix as shown in FIG. The braided battery 40 is formed by finishing as follows. Each unit polymer secondary battery body 41 has the same length, and the negative electrode terminal 42 and the positive electrode terminal 43 are located on the same side and woven.

The braided battery 40 has a flexible sheet shape as a whole since each unit polymer secondary battery body 41 has a flexible cord shape. The braided battery 40 is provided along each of two adjacent side edges of one corner, and each unit polymer secondary battery 4
One negative electrode terminal 42 is exposed and arranged, and the positive electrode terminal 43 of each unit polymer secondary battery body 41 is exposed and arranged along two adjacent side edges of opposing corners. The braided battery 40 has a structure in which the negative terminals 42 are electrically connected integrally with each other by a negative connector 44, and the positive terminals 43 are electrically connected integrally with each other by a positive connector 45. As in the case of the above-described braided battery 2, the battery 40 has a parallel specification by arranging a plurality of batteries and connecting the negative electrode connector 44 and the positive electrode connector 45 facing each other. Further, the braided battery 40 has a serial specification by superposing a plurality of the batteries and connecting the negative electrode connector 44 and the positive electrode connector 45 facing each other. The braided battery 40 is sewn as a lining on the inner surface of the vest 1, and the negative connector 44 and each positive connector 45 are connected to the connector 5. Therefore, the braided battery 40 constitutes a reserve power source for the built-in secondary battery and a charging power source for charging the portable electronic device 3 housed in the vest 1. The braided battery 40 includes the connector 5
The battery is charged by being connected to a commercial power supply or the like via the.

A braided battery 50 shown in FIG. 6 as a fourth embodiment of the present invention includes a pair of unit polymer secondary battery bodies 51a and 51b formed in a long cord shape. The braided battery 50 is formed by folding these unit polymer secondary battery bodies 51a and 51b like the braided battery 30 described above, and alternately assembling the pieces in a state of being orthogonal to each other.

Unit polymer secondary battery bodies 51a, 51b
Since it has a flexible cord shape, it constitutes a sheet-shaped braided battery 50 that is entirely flexible. In the woven battery 50, each of the unit polymer secondary battery bodies 51a and 51b has a negative electrode terminal 52 formed on one end side and a positive electrode terminal 53 formed on the other end side, and a space between the negative electrode terminals 52 is not shown. The connection is made by a negative electrode terminal member, and the positive electrode terminals 53 are connected by a positive electrode terminal member (not shown). Braided battery 50
Means that the negative electrode terminal member and the positive electrode terminal member
Connected to. In addition, the braided battery 50 has the trouble of folding the unit polymer secondary battery bodies 51a and 51b, but the man-hour for forming the negative electrode terminal 52 and the positive electrode terminal 53 can be reduced.

[0042]

As described above in detail, according to the knitted battery according to the present invention, the entirety is obtained by knitting a flexible linear unit polymer secondary battery body as a fiber material. A backup power source for a portable electronic device or the like that is configured in a flexible cloth shape and used for a lining of clothes, a portable case or a bag for storing a portable electronic device, etc., and is stored and carried in the case. Or as a charging power source for the built-in secondary battery. Therefore, the braided battery eliminates the need to carry an independent spare power supply device and configures a large-capacity power supply device, thereby enabling long-term use of a portable electronic device or the like. In addition, the braided battery charges a built-in secondary battery when it is carried or not used, thereby avoiding the inconvenience of running out of battery due to forgetting to charge a portable electronic device or the like.

Further, the battery ware provided with the braided battery according to the present invention is a cloth-like unit having a flexible linear unit polymer secondary battery body as a fibrous material, which is knitted. The braided battery constructed as described above is provided on a lining or the like to enable connection with a portable electronic device or the like which is stored in a pocket or the like and carried. It acts as a backup power supply or a charging power supply for the built-in secondary battery. Therefore, the battery ware including the braided battery does not require carrying an independent spare power supply device, and also enables a long-term use of a portable electronic device or the like by forming a large-capacity power supply device. . In addition, battery ware equipped with a woven battery can charge a secondary battery incorporated in an electronic device or the like when the device is carried or not in use, and can be used when the battery is exhausted due to forgetting to charge the portable electronic device or the like. Avoid inconveniences. Further, the battery ware including the braided battery is a portable electronic device or the like stored in a pocket or the like with the braided battery being warmed by the body temperature of the user, thereby improving low-temperature characteristics. Supply power in a stable state.

[Brief description of the drawings]

FIG. 1 is a front view of a vest shown as an embodiment of a battery ware including a braided battery according to the present invention.

FIG. 2 is a vertical cross-sectional view of a main part, illustrating a configuration of a unit polymer secondary battery constituting a braided battery.

FIG. 3 is a plan view of the braided battery.

FIG. 4 is a plan view of a braided battery shown as a second embodiment of the present invention.

FIG. 5 is a plan view of a braided battery shown as a third embodiment of the present invention.

FIG. 6 is a plan view of a braided battery shown as a fourth embodiment of the present invention.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 vest, 2 braided battery, 3 portable electronic device, 4 pockets, 5 connectors, 10 unit polymer secondary battery body, 11 negative electrode material, 12 negative electrode current collector, 13 negative electrode active material layer, 14 positive electrode material, 15 Positive electrode current collector, 16
Positive electrode active material layer, 17 solid polymer electrolyte, 18 exterior material, 19 sealant, 20 negative electrode current collecting tab, 21 positive electrode current collecting tab

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Kazuhiro Noda 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation F-term (reference) 5H029 AJ00 AK03 AK05 AL06 AL07 AM03 AM07 AM16 BJ04 BJ12 DJ00 DJ01 DJ02 EJ12

Claims (8)

[Claims] 1. A linear unit having flexibility by laminating a linear negative electrode material obtained by applying a polar active material to a current collector and a positive electrode material via a solid polymer and sealing with an exterior material. A braided battery comprising a polymer secondary battery body, and the unit polymer secondary battery body is knitted as a fiber material to be knitted into a flexible cloth as a whole. 2. The braided battery according to claim 1, wherein the unit polymer secondary battery body has a band shape. 3. The woven battery according to claim 1, wherein the unit polymer secondary battery is cord-shaped. 4. The fabric according to claim 1, wherein a large number of said unit polymer secondary battery bodies are used as a fiber material, and these are arranged in a matrix and knitted alternately in a lattice to form a fabric. The braided battery as described. 5. A fabric comprising at least one pair of elongated unit polymer secondary battery bodies as a fibrous material, and knitting them alternately in a lattice shape while folding them individually. Item 2. A braided battery according to Item 1. 6. A flexible linear member obtained by coating a linear negative electrode material and a positive electrode material obtained by applying a polar active material to a current collector through a solid polymer electrolyte and sealing with a sheath material. And a knitted battery formed by knitting the unit polymer secondary battery body as a fibrous material into a fabric having flexibility as a whole. A battery ware which can be connected to an electronic device or the like stored in a pocket or the like. 7. The battery ware according to claim 6, wherein the braided battery forms an auxiliary power supply of the electronic device. 8. The batteryware according to claim 6, wherein the braided battery constitutes a charging power source for charging a built-in secondary battery mounted on the electronic device.