Battery

Information

  • Patent Application
  • 20120052344
  • Publication Number
    20120052344
  • Date Filed
    August 25, 2011
    13 years ago
  • Date Published
    March 01, 2012
    12 years ago
Abstract
An internal resistance is maintained equal to or lower than 70 mΩ, and that a temperature rise of a battery during an external short circuit at an ambient temperature of 23° C. with a margin of error of plus or minus 2° C. does not exceed 45° C.
Description
CROSS-REFERENCE TO RELATED APPLICATION

The present application claims the benefit of priority of Japanese Patent Application No. 2010-195821, filed Sep. 1, 2010, and Japanese Patent Application No. 2010-195822, filed Sep. 1, 2010. The entire disclosures of the priority applications are incorporated herein by reference in their entirety.


BACKGROUND OF THE INVENTION

1. Field of the Invention


The invention relates to a battery, and more specifically, to a small battery such as an AA-size battery that has been widely used.


2. Description of the Related Art


In recent years, small batteries such as AA-size batteries and those of a compatible shape, typified by alkaline storage batteries, have been very widely used in electric appliances, toys, etc. These small batteries include cylindrical storage batteries, such as manganese batteries, alkaline manganese batteries, nickel batteries, and nickel hydrogen batteries.


A cylindrical storage battery has a positive terminal and a negative terminal in the outer surface of a casing, and is so configured that the casing contains the members constituting an electrode group, that is, positive and negative plates and a separator.


These small batteries are known to generate heat due to the excessive current that flows inside the casing when there is a short circuit outside the casing.


Given this factor, various kinds of batteries have been developed, which prevents excessive current by using a resistor element and thus avoids heat generation in the event of a short circuit outside the casing (see Unexamined Japanese Patent Publication No. 58-188066 (hereinafter referred to as Patent Document 1), Unexamined Japanese Patent Publication No. 10-275612 (hereinafter referred to as Patent Document 2), and Unexamined Japanese Patent Publication No. 2002-110137 (hereinafter referred to as Patent Document 3)).


However, the batteries disclosed in Patent Documents 1 to 3 have the problem that if the resistor element has a high resistance value, this degrades the performance of the batteries under normal use.


Particularly, the battery disclosed in Patent Document 2 is configured so that a resistor element is placed outside the casing. This produces a high amount of heat generation of the resistor element outside the casing, which is not preferable.


There are battery packs consisting of a plurality of batteries, the safety of which is ensured by installing a PTC (positive temperature coefficient) thermistor in a conductive path


The PTC thermistor is installed with the purpose of controlling current in the battery to prevent a rapid temperature rise utilizing the PTC thermistor's property that electric resistance increases, and thus ensuring the safety.


The PTC thermistor controls current, for example, using insulating polymer in which conductive particles are dispersed, utilizing the property that the entire insulating polymer is expanded by the heat generated when high current flows due to an external short circuit or the like, and that this expansion reduces contact between the conductive particles and causes an abrupt increase in resistance value.


Needless to say, once the heat generation is discontinued, the insulating polymer cools down and shrinks, and the resistance value is reduced again.


One possible solution is to incorporate the PTC thermistor serving as a resistor element into a one-cell battery so as to be placed along another hard member.


In the foregoing configuration, however, the expansion of the insulating polymer in the PTC thermistor is hampered, and an excessive current cannot be fully prevented. In result, there remains the problem that the heat generation cannot be adequately controlled.


As a way to take advantage of the above property of the PTC thermistor, it has been under consideration to install the PTC thermistor in a portion of a conductive member that conducts between the terminals situated outside the casing and the electrode plates situated inside the casing, or more specifically, as described in Patent Document 1, a portion of a positive tab that conducts between a positive terminal and a positive plate, the portion being exposed in an interior space of the casing.


The interior space of the casing between the positive terminal and the positive plate, in which the PTC thermistor is placed, is filled with a gas atmosphere that is a mixture of an oxygen constituent (high-pressure oxygen atmosphere) produced by chemical reaction during charge/discharge and an alkaline constituent (alkaline atmosphere) produced by electrolyte existing inside the battery.


When exposed to an oxygen atmosphere and an alkaline atmosphere, however, the PTC thermistor is influenced by oxygen and alkaline constituents, and fails to fulfill the function of controlling current. The oxygen constituent in the atmosphere erodes the resin of the PTC thermistor and a conductive agent, and the alkaline constituent erodes a soldered part (bonded part) in which the PTC thermistor and the positive tab are bonded together. In result, the PTC thermistor is deteriorated or becomes nonfunctional.


To solve the above issue, the PTC thermistor installed in the casing is pinched inside a sealed module constituting a part of the casing of the cylindrical storage battery as shown in Patent Document 2 or is placed in the electrode plates of the electrode group of a cylindrical storage battery as shown in Patent Document 3. In this way, the PTC thermistor is incorporated and sealed inside a component situated in a place other than the interior space of the casing, thereby being protected from deterioration. In some cases, to encourage the protection of the PTC thermistor, the entire sealed module and the PTC thermistor of the electrode group are sealed with a synthetic resin member.


On the other hand, in order to incorporate the PTC thermistor into a narrow area, such as a sealed module and the electrode plates of an electrode group shown in Patent Documents 2 and 3, it is required to situate the PTC thermistor along another hard member. In other words, the PTC thermistor is surrounded by the components of the hard sealed module, the hard members of the electrode group, etc. The PTC thermistor therefore possibly interferes with these components and members, and is prevented from being expanded, failing to adequately fulfill the function of controlling current.


Especially, in the case of the configuration where the PTC thermistor is placed in the electrode group of the battery as in Patent Document 3, there is a concern that the heat generation caused by battery charge/discharge may influence the operations of the PTC thermistor. That is to say, if placed in the electrode section, the PTC thermistor is located close to a heating element and is therefore influenced by the temperature produced by the batter charge/discharge. The PTC thermistor comes to a temperature close to Trip (resistance rise reaction) temperature as a result of normal charge/discharge. Once this happens, an initial resistance value is slowly increased during the use of the PTC thermistor, and resistance is not successfully recovered after the PTC thermistor's temperature reaches the Trip temperature and then drops down.


Moreover, in the configuration where the PTC thermistor is placed in the electrode section, even if the positive tab generates heat during short circuit, it takes time until the PTC thermistor starts operating due to a large distance between the positive tab and the interior of the electrode group in which the PTC thermistor is placed. In other words, even if the PTC thermistor comes into a Trip state after the positive tab reaches the Trip temperature, a separator between the positive tab and the PTC thermistor is melted by heat, and one of the electrode plates might contact the other, which hinders the PTC thermistor's function of ensuring safety.


For the above-mentioned reason, it is difficult to retain the reliability of the PTC thermistor and make the PTC thermistor ensure the safety of the battery.


SUMMARY OF THE INVENTION

An aspect of the present invention is directed to a battery in which an internal resistance is equal to or lower than 70 mΩ, and a temperature rise of the battery during an external short circuit at an ambient temperature of 23° C. with a margin of error of plus or minus 2° C. does not exceed 45° C.





BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood from the detailed description given hereinafter and the accompanying drawings which are given by way of illustration only, and thus, are not limitative of the present invention, and wherein:



FIG. 1 is a perspective view, partially cut away, showing the entire structure of a nickel hydrogen battery according to one embodiment of the invention;



FIG. 2 is a cross-sectional view showing a PTC thermistor that is situated in a positive tab of the nickel hydrogen battery;



FIG. 3 is a perspective view showing a protection structure of the PTC thermistor; and



FIG. 4 is an exploded perspective view showing the protection structure of the PTC thermistor.





DETAILED DESCRIPTION OF THE INVENTION

The present invention will be described below on the basis of one embodiment shown in FIGS. 1 to 4.



FIG. 1 is a perspective view, partially cut away, showing a battery applied to the invention, for example, an AA-size nickel hydrogen battery that is one type of an AA-size alkaline storage battery. FIG. 2 is a cross-sectional view showing in an enlarged scale a structure of a positive-electrode side of the nickel hydrogen battery. In this specification, an AA-size nickel hydrogen battery has a height ranging from 49.2 mm to 50.5 mm and an external diameter ranging from 13.5 mm to 14.5 mm. In FIGS. 1 and 2, a cylindrical casing of the nickel hydrogen battery is provided with reference mark “1”.


As shown in FIGS. 1 and 2, the casing 1 is formed of a conductive cylindrical outer can 2, a conductive disc-shaped sealed module 4 (collection of various members 4) that is situated to block an opening of the outer can 2, and a ring-shaped insulating member 3 that insulates between an opening edge of the outer can 2 and an outer periphery of the sealed module 4. The casing 1 is sealed.


An electrode group is contained in the outer can 2 constituting the casing 1. As shown in FIGS. 1 and 2, the electrode group is formed of a laminate sheet 9 that is made by rolling into a spiral shape a strip-shaped positive plate 6 that is filled, for example, with nickel hydroxide particles (positive active material), a strip-shaped negative plate 7 that is filled, for example, with hydrogen storage alloy (negative active material), and an insulating separator 8 maintaining an alkaline electrolyte and intervening between the positive plate 6 and the negative plate 7. Needless to say, the wound components are insulated by an insulating member 9a to avoid short circuit. A lateral edge of the negative plate 7, that is, a pantograph terminal 7a formed in a lower edge of the negative plate 7, is conducted to the outer can 2 through a plate-shaped negative pantograph member 10. The pantograph terminal 7a and the negative pantograph member 10 constitute a negative terminal 12 in a bottom face of the outer can 2.


As shown in FIGS. 1 and 2, a lateral edge of the positive plate 6, that is, a pantograph terminal 6a formed in an upper edge of the positive plate 6, is conducted to a plate-shaped positive pantograph member 13 having a through-hole 13a. The positive pantograph member 13 is a component installed right above the electrode group. The positive pantograph member 13 is connected to the sealed module 4 through a conducting member, or a positive tab 15, situated in an interior space 2a of the casing which is created between the electrode group and the sealed module 4. A protrusion 4a formed in a center of an outer face of the sealed module 4 serves as a positive terminal 5. Installed in the protrusion 4 serving as the positive terminal 5 is a relief valve 16 that releases the gas generated inside the battery when the gas increases an inner pressure equal to or higher than predetermined pressure. A member provided with a reference mark “16a” in FIGS. 1 and 2 is a valve body of the relief valve 16, and a member with “16b” is a spring. The relief valve 16 is not necessarily of a spring-valve type, and may be formed in another valve structure, such as a rubber-valve type structure. The relief valve 16 only has to allow the gas to escape.


As shown in FIGS. 1 and 2, a thin plate-shaped PTC thermistor 20 is situated in the positive tab 15. The positive tab 15 is divided, for example, in the middle into an L-shaped tab portion 15a extending from the positive pantograph member 13 and a U-shaped tab portion 15b extending from the sealed module 4. The PTC thermistor 20 is situated between a tip end of the tab portion 15a and that of the tab portion 15b, which are detached away from and opposite to each other. FIG. 3 is a perspective view showing a protection structure of the PTC thermistor 20. FIG. 4 is an exploded perspective view showing the protection structure of the PTC thermistor 20.


According to an example shown in FIGS. 2, 3 and 4, upper and lower faces of the PTC thermistor 20 are soldered to the tip ends of the tab portions 15a and 15b, respectively.


The PTC thermistor 20 is accordingly arranged in series in the positive tab 15. In order to enhance the adhesiveness of the PTC thermistor 20, a fixed structure is employed in which the PTC thermistor 20 is soldered by solder 22 to a pair of metal plates, not shown, constituting a connection terminal between the PTC thermistor 20 and the tip ends of the tab portions 15a and 15b, with a nickel film 21 intervening therebetween as shown in FIG. 4.


The PTC thermistor 20 is made, for example, of insulating polymer in which conductive particles are dispersed. Current is thus controlled utilizing the property that the entire insulating polymer is expanded by the heat generated when high current flows due to a short circuit that occurs outside the casing, and the like, and that this expansion reduces contact between the conductive particles and causes an abrupt increase in resistance value. Once the heat generation is discontinued, the insulating polymer cools down and shrinks, and the resistance value becomes low again.


The PTC thermistor 20 disposed in the interior space 2a of the casing can be expanded without difficulty because there is not any hard component or member nearby, which might interfere with the PTC thermistor 20. Furthermore, a surrounding environment of the PTC thermistor 20 is not likely to influence the properties and operations of the PTC thermistor 20. On the other hand, the PTC thermistor 20 might be deteriorated because it is exposed to a gas atmosphere filled in the interior space 2a of the casing, or more specifically, a gas atmosphere that is a mixture of an oxygen constituent (high-pressure oxygen atmosphere) produced by chemical reaction during charge/discharge and an alkaline constituent (alkaline atmosphere) produced by electrolyte, not shown, existing inside the battery.


Given the foregoing factor, some means has been taken to prevent the deterioration of the PTC thermistor 20 without hindering the functions of the PTC thermistor 20 and influencing the operations of the PTC thermistor 20. As this means, the present embodiment employs a structure that protects the PTC thermistor 20 from the oxygen and alkaline constituents contained in the gas atmosphere by coating the periphery of the PTC thermistor 20 with a flexible protection layer 25 as shown in FIGS. 1 and 2. The protection structure of the PTC thermistor 20 is particularly illustrated in FIGS. 2 and 3. For easy understanding of the protection structure, FIGS. 2 and 3 show each part of the protection layer 25 on a slightly large scale.


The protection structure will be described below. As shown in FIGS. 2 and 3, the protection layer 25 is formed in a multilayer structure of an oxygen-proof protection layer 27 that is disposed to cover the periphery of the PTC thermistor 20 and blocks the passing of the oxygen constituent in the gas atmosphere, and an alkali-proof protection layer 29 that is disposed to cover the periphery of the oxygen-proof protection layer 27 and blocks the passing of the alkaline constituent in the gas atmosphere. In the oxygen-proof protection layer 27, for example, flexible epoxy resin members 27a, shown only in FIG. 4, are applied onto the periphery of an overlapping part of the tab portions 15a and 15b, where the PTC thermistor 20 intervenes therebetween, and the PTC thermistor 20. In other words, the oxygen-proof protection layer 27 is formed so that the overlapping part of the tab portions 15a and 15b, where the PTC thermistor 20 intervenes therebetween, and the PTC thermistor 20 are covered with the epoxy resin members 27a. It is a matter of course that any other synthetic resin members than the epoxy resin members 27a may be utilized as long as they are synthetic resin members having flexibility and resistance properties against the oxygen constituent.


The alkali-proof protection layer 29 includes, for example, a flexible thin tape 30 made of polypropylene, that is, two pieces of polypropylene tape 30 as shown in FIGS. 3 and 4. The polypropylene tape 30 is applied so as to sandwich a coat layer made of one of the epoxy resin members 27a corresponding to one side of the PTC thermistor 20 and a coat layer made of the other epoxy resin members 27a corresponding to the other side of the PTC thermistor 20, and to cover the whole periphery of the coat layers of the epoxy resin members 27a. In short, the alkali-proof protection layer 29 is formed of a polypropylene tape layer. The alkali-proof protection layer 29 may be coated with polypropylene, instead of being formed of the tape 30, or may be formed of another member that is flexible and blocks the passing of the alkaline constituent, for example, a nylon-based member, such as nylon 6, nylon 11, nylon 12, nylon 66, nylon 610, nylon 6T, nylon 9T, nylon M5T, and nylon 612, polyamide-based resin, alkali-proof rubber, mineral synthetic resin (asphalt) or the like.


Assuming that, for example, a short circuit outside the casing (or an excessive high current charge/discharge) occurs in the nickel hydrogen battery configured as described above, the entire insulating polymer is expanded in the PTC thermistor 20 by the heat generated when high current flows at the time of the short circuit, which reduces contact between the conductive particles and rapidly increases the resistance value. As the expansion of the insulating polymer takes place in the interior space 2a of the casing in which there is not any hard member nearby, which might interfere with the PTC thermistor 20, the resistance value of the PTC thermistor 20 is quickly increased to a required resistance value. The current is thus controlled, and the heat generation of the battery is prevented. When a current value is restored to a normal value (or when battery discharge is finished), the resistance value of the PTC thermistor 20 returns to a lower value.


At this point of time, the interior space 2a of the casing is filled with the gas atmosphere that is the mixture of the oxygen constituent (high-pressure oxygen atmosphere) produced by chemical reaction during charge/discharge and an alkaline constituent (alkaline atmosphere) produced by the electrolyte existing in the battery. This causes a concern that the PTC thermistor 20 (resin) and the bonded part (soldered part) of the PTC thermistor 20 might be eroded by the above constituents.


Since the entire PTC thermistor 20 is covered with the oxygen-proof protection layer 27 as shown in FIGS. 2, 3 and 4, the PTC thermistor 20 itself is prevented from being eroded by the oxygen constituent. The periphery of the oxygen-proof protection layer 27 is covered with the alkali-proof protection layer 29, so that the oxygen-proof protection layer 27 is protected from the erosion attributable to the alkaline constituent, preventing the erosion of the soldered part in which the PTC thermistor 20 and the tab portions are bonded together.


The protection layer 25 thus protects the PTC thermistor 20 (resin) and the soldered part of the PTC thermistor 20 from the oxygen and alkaline constituents contained in the gas atmosphere. Because of flexibility, the protection layer 25 does not hinder the expansion of the PTC thermistor 20.


For that reason, the PTC thermistor 20 is easily expanded. Due to the combination of the installation of the PTC thermistor 20 into the interior space 2a of the casing to be located at a position where the properties and resistance recovery of the PTC thermistor 20 are not influenced, and the coating of the PTC thermistor 20 with the flexible protection layer 25, it is possible to make the PTC thermistor 20 fully exert the property of controlling high current and control the heat generation of the battery without influencing the oxygen and alkaline constituents contained in the gas atmosphere filling the interior space 2a of the casing and without hindering the properties and operations of the PTC thermistor 20.


Consequently, the safety of the battery can be sufficiently ensured by using the PTC thermistor 20.


The protection layer 25 is simply configured in a multilayer structure that is formed of the oxygen-proof protection layer 27 covering the PTC thermistor 20 and the alkali-proof protection layer 29 covering the periphery of the oxygen-proof protection layer 27. Especially, the oxygen-proof protection layer 27 is formed by the coating with the epoxy resin member 27a, whereas the alkali-proof protection layer 29 is formed by the application of a plurality of strips of the polypropylene tape 30. In this way, both the layers are formed by simple work, thereby preventing the deterioration of the PTC thermistor 20 without difficulty.


Embodiment

An embodiment of the battery according to the invention will be described below in comparison with conventional batteries of various kinds.


As shown in TABLES 1 and 2, a research was conducted on operating voltage during 740-mA discharge, temperature rise during an external short circuit in a charging state at an ambient temperature of 23° C. with a margin of error of plus or minus 2° C., whether there is a liquid leakage after short circuit, and the reusability after short circuit, while varying the kinds of batteries, internal resistance, presence or absence of the PTC thermistor 20, and cable short circuit resistance. TABLE 1 shows a case in which the cable short circuit resistance is 2.5 mΩ, and TABLE 2 shows a case in which the cable short circuit resistance is 100 mΩ.


In TABLES 1 and 2, Embodiment 1 is a nickel hydrogen battery having the above-described configuration and having an internal resistance of 25 mΩ. In TABLES 1 and 2, Embodiment 2 is a nickel hydrogen battery having the above-described configuration and having an internal resistance of 70 mΩ.


In TABLES 1 and 2, Comparative Example 1 is a nickel hydrogen battery having a PTC thermistor and having an internal resistance of 80 mΩ.


In TABLES 1 and 2, Comparative Example 2 is a nickel hydrogen battery having a PTC thermistor and having an internal resistance of 130 mΩ.


In TABLES 1 and 2, Comparative Example 3 is a nickel hydrogen battery that does not have a PTC thermistor and has an internal resistance of 23 mΩ.


In TABLES 1 and 2, Comparative Example 4 is an alkaline manganese battery that does not have a PTC thermistor and has an internal resistance of 110 mΩ.


In TABLES 1 and 2, Comparative Example 5 is a manganese battery that does not have a PTC thermistor and has an internal resistance of 400 mΩ.


In TABLES 1 and 2, Comparative Example 6 is a nickel battery that does not have a PTC thermistor and has an internal resistance of 100 mΩ.
















TABLE I





Cable short




Temperature rise




circuit

Internal

Operating voltage
during short circuit
Liquid leakage
Reusability


resistance

resistance
PTC
(740-mA discharge)
in a charging state
after short
after short


2.5 mΩ
Battery
(mΩ)
thermistor
(V)
(° C.)
circuit
circuit






















Embodiment 1
Nickel hydrogen
25
Present
1.260
20
Absent
Reusable



battery


Embodiment 2
Nickel hydrogen
70
Present
1.200
15
Absent
Reusable



battery


Comparative
Nickel hydrogen
80
Present
1.190
15
Absent
Reusable


Example 1
battery


Comparative
Nickel hydrogen
130
Present
1.140
25
Absent
Reusable


Example 2
battery


Comparative
Nickel hydrogen
23
Absent
1.260
110
Present
Nonreusable


Example 3
battery


Comparative
Alkaline manganese
110
Absent
1.172
100
Present



Example 4
battery


Comparative
Manganese battery
400
Absent
1.100
60
Absent



Example 5


Comparative
Nickel battery
100
Absent
1.338
100
Present



Example 6























TABLE II





Cable short




Temperature rise




circuit

Internal

Operating voltage
during short circuit
Liquid leakage
Reusability


resistance

resistance
PTC
(740-mA discharge)
in a charging state
after short
after short


100 mΩ
Battery
(mΩ)
thermistor
(V)
(° C.)
circuit
circuit






















Embodiment 1
Nickel hydrogen
25
Present
1.260
15
Absent
Reusable



battery


Embodiment 2
Nickel hydrogen
70
Present
1.200
11
Absent
Reusable



battery


Comparative
Nickel hydrogen
80
Present
1.190
12
Absent
Reusable


Example 1
battery


Comparative
Nickel hydrogen
130
Present
1.140
30
Absent
Reusable


Example 2
battery


Comparative
Nickel hydrogen
23
Absent
1.260
65
Absent
Reusable


Example 3
battery


Comparative
Alkaline manganese
110
Absent
1.172
73
Absent



Example 4
battery


Comparative
Manganese battery
400
Absent
1.100
53
Absent



Example 5


Comparative
Nickel battery
100
Absent
1.338
85
Absent



Example 6









In the batteries of Embodiments 1 and 2 of the invention, the operating voltage during 740-mA discharge under the normal use of the battery can be made equal to or higher than 1.20 V by setting the internal resistance at 25 mΩ or 70 mΩ, that is, by setting the internal resistance equal to or lower than 70 mΩ. If the cable short circuit resistance is 2.5 mΩ or 100 mΩ, the temperature rise during an external short circuit at an ambient temperature of 23° C. with a margin of error of plus or minus 2° C. can be controlled not to exceed 45° C. due to the functions of the PTC thermistor, thereby meeting official standard values (ST standard of the Japan Toy Association, for example).


The batteries of Embodiments 1 and 2 of the invention do not cause a liquid leakage after short circuit and are reusable after short circuit without problems.


Accordingly, the batteries of the invention are improved in safety by preventing heat generation during an external short circuit without being degraded in performance under normal use.


Nickel hydrogen batteries and AA-size batteries, especially, AA-size nickel hydrogen batteries, are very widely used in electric appliances, toys, etc., so that the invention can be suitably applied to these batteries that are very widely used.


This is the end of the battery according to the invention, but the invention is not limited to the above-described embodiment.


For example, the embodiments use the protection layer of a two-layer structure. However, a protection layer including more than two layers or a protection layer including a single layer added with various protective constituents may be utilized. The embodiments mention an example in which a PTC thermistor is used in a positive tab. In the case of an alkaline storage battery with a negative tab, however, a PTC thermistor may be used in the negative tab, and the structure of the protection layer may be employed. Although the embodiments refer to a battery structure including the positive pantograph member, it is also possible to use a battery structure in which the positive tab is directly attached onto the positive plate, instead of using the positive pantograph member.


For example, in the above embodiments, the battery is a nickel hydrogen battery. The battery, however, is not limited to a nickel hydrogen battery and may be another battery as long as the same effects can be obtained as with the nickel hydrogen battery.


The invention being thus described, it will be obvious that the same may be varied in ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.

Claims
  • 1. A battery wherein an internal resistance is equal to or lower than 70 mΩ, and that a temperature rise during an external short circuit at an ambient temperature of 23° C. with a margin of error of plus or minus 2° C. does not exceed 45° C.
  • 2. The battery according to claim 1, wherein the battery is an AA-size battery.
  • 3. The battery according to claim 1, wherein the battery is a nickel hydrogen battery.
  • 4. The battery according to claim 1, the battery has a casing provided with a positive terminal and a negative terminal on an outer surface; the casing contains a positive plate, a negative plate, and a separator; at least one of the terminals and the corresponding electrode plate are conducted to each other by a conducting member situated in the casing; wherein the conducting member includes a PTC thermistor in a portion exposed in an interior space in the casing; andthe PTC thermistor is coated with a flexible protection layer that protects the PTC thermistor from an oxygen constituent and an alkaline constituent, which are contained in a gas atmosphere filled in the interior space of the casing.
  • 5. The battery according to claim 4, wherein the conducting member is a positive tab that conducts between the positive terminal and the positive plate.
  • 6. The battery according to claim 4, wherein the protection layer is configured in a multilayer structure including a flexible oxygen-proof protection layer that covers the periphery of the PTC thermistor and a flexible alkali-proof protection layer that covers the periphery of the oxygen-proof protection layer.
  • 7. The battery according to claim 6, wherein the oxygen-proof protection layer is formed by coating the periphery of the PTC thermistor with an epoxy resin member; wherein the alkali-proof protection layer is formed by covering the periphery of the coating layer of the epoxy resin member with a plurality of strips of polypropylene tape.
Priority Claims (2)
Number Date Country Kind
JP 2010-195821 Sep 2010 JP national
JP 2010-195822 Sep 2010 JP national