The present invention relates to a PTC device as well as an electrical device, for example a secondary battery, comprising same.
A polymer PTC component, comprising a laminar PTC element containing a conductive filler and a polymer material, and a metal electrode disposed on a surface of each side of the polymer PTC element, is widely used in various electrical devices. For example, such a PTC component is used as a circuit protection device in a secondary battery charging circuit in order to prevent a problem of overcharging and the like when a secondary battery of a cell phone is charged. This PTC component is disposed in a protection circuit via leads, and a PTC device comprising the PTC component and the leads, and the protection circuit are disposed outside the positive electrode terminal; these together make up an electrical device, and are used as the so-called a “battery pack”. Since an electrical apparatus has the battery pack embedded therein, the electrical apparatus may be made more compact if the embedded battery pack could be made more compact.
On the other hand, various types of dry-cell type secondary batteries are used. Among such secondary batteries, in the case of a size AA or a size AAA cell for example, because there is a constraint in enlarging the volume it occupies, no PTC component is not provided therein.
The electrolyte used comprises an alkali as a base and contains for example a potassium salt such as potassium hydroxide. Various salts, such as those of sodium, lithium, etc., are used as other alkalis in some cases. Such alkalis are generally corrosive so that the positive electrode tab is exposed to an environment of such alkali. Therefore, a material having resistance to the alkaline corrosion needs to be selected for the material to be used as the positive electrode tab. For example, nickel is used as the material of the positive electrode tab. Nickel forms a passive material in the alkaline environment, as a result of which it has resistance to the corrosion.
A battery is shown in Japanese Patent Publication No. 2008-181855.
The inventors concentrated their investigation on making a PTC device and an electrical device such as a battery pack comprising the PTC device and a secondary battery, and a dry-cell type secondary battery more compact, as a result of which it has been concluded that, in the above dry-cell type secondary battery, if the PTC device could be disposed in a space 112 where the positive electrode tab 106 exists (this space may herein also be called a “positive electrode tab space”), the volume of the secondary battery may be made smaller. Also, it has been concluded that, in the battery pack, if the PTC device disposed outside the secondary battery could be disposed within the secondary battery, the volume of the battery pack may be made smaller.
However, in order to dispose the PTC device in the positive electrode tab space, or to dispose the PTC device within the secondary battery of the battery pack, the alkaline corrosion as described above needs to be considered. After further studies as to this, it has been found that, among the various elements forming the PTC device, by covering a part(s) that may be adversely affected by the corrosion, etc., by the alkali contained in the electrolyte of the secondary battery with a polypropylene resin, a nylon resin or an epoxy resin, such adverse effects can be suppressed to a minimum, resulting in the PTC device of the present invention.
Therefore, according to the first aspect, the present invention provides a PTC device comprising:
Among the elements constituting the PTC device of the present invention, the PTC component is well-known, and such a PTC component may be used in the present invention. The lead is an element required to electrically connect the PTC component to a prescribed circuit; this per se also is well-known, and such a lead, e.g. a nickel lead, a nickel-plated stainless steel lead, a nickel-iron alloy (Kover™) lead, and the like, may be used in the present invention. Further, the electrically conductive material connecting the metal electrode of the PTC component to the lead is well-known, and is not restricted in particular as long as they are able to be electrically connected to each other; in the present invention also, such an electrically conductive material may be used. For example, a solder, a solder paste, an electrically conductive adhesive, and the like, may be used. In the PTC device, such electrically conductive material may be a state (for example, a state after curing of an element of the composition such as a setting resin) which is changed from its original state (for example, a state before curing of the element of the composition such as a setting resin) in order to have a function for connecting.
The present invention is useful in a case where such an electrically conductive material may be adversely affected, e.g. corroded, by the electrolyte constituting the battery, in particular an alkaline component contained therein, for example a salt and/or an ion of an alkaline metal such as sodium, potassium, lithium, etc. In particular, such case corresponds to a case wherein an electrically conductive material contains, for example, tin, zinc, lead, or the like. The present invention is particularly useful when using in particular a solder as the electrically conductive material, in particular a lead-free solder, for example an alloy solder of tin, silver and copper, an alloy solder of tin and bismuth, an alloy of tin and indium, or the like.
In the present invention, “a polypropylene resin, a nylon resin, or an epoxy resin” may be any commonly-known resin as long as the problem of the invention can be solved. For example, in the case of the polypropylene resin, a syndiotactic type is preferably used. For example, in the case of the nylon resin, 6,6-nylon is preferably used, and a resin with high crystallinity is more preferably used. For example, in the case of the epoxy resin, particularly a resin with an excellent chemical resistance, for example a two-component epoxy resin formed from an epoxy resin prepolymer and a polyamine resin is preferably used.
In the PTC device of the present invention, the protective member may be in any suitable form. The protective member may be in the form of a protective coating. In this case, the resin as described above is applied, for example by brushing, spraying, etc., so as to cover the exposed part. As needed, it is preferred that a suitable form for applying the resin in the above way, for example, a solution, a dispersed liquid or the like of the resin is obtained by using a solvent or the like, and this is applied, and as necessary, the solvent or the like is dried (for example, removed by heating). Specifically, it is preferred that this form is used when forming a protective member containing an epoxy resin.
In another embodiment, a film may be obtained from the resin as described above, and the PTC component may be enveloped by this film so that only the end of the lead protrudes. In other words, the protective member may be in a film form enveloping the PTC component or a form wherein two pieces of film sandwich the PTC component therebetween. The protective member may be formed by using, for example, a polypropylene resin film, specifically a biaxial oriented polypropylene (OPP), or a nylon resin film. The polypropylene resin film may also be a layer which is called a K coat film (KOP). This film is a polypropylene film which is coated with a PVDF (polyvinylidene fluoride) resin on one surface or both surfaces thereof, and is effective in that it has an improved gas barrier property.
In a preferred embodiment of the present invention, such a film is used with at least one, for example one or two additional layers laminated thereon. Examples of the additional layers include, for example, an EVA (ethylene-vinyl acetate copolymer) layer, an EVOH (ethylene-vinyl alcohol copolymer) layer, a PVDF (polyvinylidene fluoride) layer, a PVA (polyvinyl alcohol) layer, a PVDC (polyvinylidene chloride) layer, a PE (polyethylene) layer, an L-LDPE (linear low density polyethylene) layer, and the like, for the purpose of improving an adhesion of the film to the exposed part of the PTC component, the leads, etc., for the purpose of improving a gas barrier property, and/or for the purpose of improving workability. When using such laminated film, the film is wrapped so that the polypropylene resin film or layer (for example, a biaxial oriented polypropylene (OPP) layer) or the nylon resin film or layer is positioned far from the PTC component.
The PE layer and the L-LDPE layer are effective in improving adhesion; the PVA layer and the PVDC layer are effective in improving a gas barrier property; the EVA layer is effective in improving both the adhesion and the gas barrier property; the EVOH layer is effective in improving the gas barrier property and an easy workability.
When using the laminated film, as described above, a laminated film may be used wherein, for example, the following combinations of the resin layers are laminated:
In a further embodiment, most of the PTC component, including the exposed part, may be enveloped by the protective member containing the resin, as described above, by insert molding wherein the above described resin in a molten form is injected into a mold in which the PTC component is disposed on (or inserted into) the mold beforehand. In other words, the protective member may be a molded member of the above described resin enveloping the PTC component.
In the broadest aspect of the present invention, in the PTC device of the present invention, the “protective member comprising a polypropylene resin, a nylon resin or an epoxy resin” is disposed such that at least a portion of a periphery of the PTC component is covered. In other words, said portion is the exposed part of the electrically conductive material as described above. For example, substantially the exposed part only, or the exposed part and its surrounding part are covered with such member. Needless to say, the protective member may cover substantially the entirety of the PTC component and the exposed part of the lead (in other words, parts which are exposed to an environment atmosphere, if the protective member is absent), with the exception of the lead end.
Various such PTC devices of the present invention can be disposed inside a secondary battery, in particular within its positive electrode tab space, and function as a positive electrode tab. Therefore, the present invention, in the second aspect, provides a secondary battery as an electrical device. Such a secondary battery may be a dry cell type or in the form of a battery pack including a PTC device on its outside. It is noted that as far as the PTC device of the present invention can be used as a protective component, the present invention also provides for other electrical devices containing such a PTC device.
This secondary battery comprises a positive electrode, a negative electrode and a separator and an electrolyte disposed therebetween, and is characterized by having the PTC device of the present invention, more specifically the leads of the PTC device, electrically connected, directly or indirectly, to and between the positive electrode and the positive electrode tab. Such a secondary battery of the present invention may be a dry cell type or in the form of a battery pack including a protection circuit on its outside of the secondary battery.
In the PTC device of the present invention, because the exposed part of the electrically conductive material, which is likely to be adversely affected by the corrosion due to an alkali contained in the electrolyte, is covered by the protective member comprising “a polypropylene resin, a nylon resin or an epoxy resin” and these resins have alkali resistance, even if the PTC device is disposed under an alkaline environment, the protective member suppresses that the alkali substantially reaches the electrically conductive material, as a result of which the effect of the corrosion on the electrically conductive material, and therefore the PTC device, is able to be suppressed to a minimum.
Thus, even if the PTC device is disposed under an environment of the electrolyte contained in the secondary battery, or the electrolyte and the PTC device accidentally come in contact, the adverse effect that the PTC device receives from the electrolyte is minimal, so that the PTC device can function as a circuit protection device.
In particular, when the PTC device is disposed in an extra space (in the sense that the PTC device is able to be accommodated therein) within the secondary battery, a space needed for the PTC device may be saved. For example, the PTC device of the present invention may be disposed in the above mentioned positive electrode tab space of the secondary battery.
The present invention is described in more detail below with reference to the drawings.
The lead 24 is connected electrically to a part of the metal electrode 18 by an electrically conductive material 28, and the lead 26 is connected electrically to the entire metal electrode 20 by an electrically conductive material 30. As a result, the electrically conductive material has an exposed part on the side surface 32 of the PTC component 22 if there is no protective member present.
In the PTC device 10 of the present invention, such exposed parts of the electrically conductive material are covered by the protective members as a protective coating 34 comprising a polypropylene resin, a nylon resin or an epoxy resin.
The protective coating may be in any form; in the embodiment shown in
Such a PTC device may be produced by inserting a PTC component connected to leads by a conductive material into a mold, then performing injection molding wherein a molding material containing or consisting of a polypropylene resin, a nylon resin or an epoxy resin in its molten state is injected into the mold and solidified, thereby forming the molded member 48 as a protective member so as to cover the exposed surface of the PTC component 42 including the exposed parts of the electrically conductive material. However, as shown in
Such a PTC device may be produced by sandwiching a PTC component having leads electrically connected by a conductive material between two pieces of the films, with the ends of the leads protruding from the films, and then compression bonding, for example thermal compression bonding (i.e. heat sealing) the films together. In this embodiment, it is preferred that the film has an additional layer(s) on its inside to secure an improved adhesion between the film and the PTC component and the lead. As to the additional layer, the EVA layer, the EVOH layer, the PVDF layer as described above are suitably used.
In another embodiment, the secondary battery of the present invention has a protection circuit on its outside and comprises the PTC device of the present invention disposed on the outside of the secondary battery, for example, on the outside of the positive electrode. In this case, in such a secondary battery, the PTC device is disposed within the protection circuit. These together work to protect the secondary battery, and the secondary battery, the PTC device and the protection circuit constitute a battery pack. Thus, even when the PTC device is disposed outside of the secondary battery, if there is a slight leak of the electrolyte in the secondary battery, the adverse effects from the electrolyte to the electrically conductive material may be suppressed.
A PTC device A of the present invention as shown in
The film used was a laminated film of a polypropylene resin layer and a polyethylene resin layer (thickness: 100 μm). This film was used so that the polypropylene resin layer was on the outside.
Other conditions are shown below:
PTC component used (trade name: PolySwitch, manufactured by Tyco Electronics Japan G.K.)
Lead: nickel (trade name: NB201, manufactured by Neomax Co., Ltd., thickness: 150 μm)
Conductive Material: lead-free solder (alloy solder of tin, silver and copper)
Thermal compression bonding condition: Pressed for 10-40 seconds at a temperature of 160° C.-210° C. under a pressure of 0.4 MPa.
A PTC device B of the present invention shown in
The PTC devices A and B thus obtained were subjected to an alkali immersion experiment which was conducted by immersing them in a KOH aqueous solution (1N) at 60° C. for 3 months. The condition of the interface between the protective member and the lead was observed to evaluate the effect of alkali. A holding current test (I-V test) was performed on the PTC devices after the immersion. Also, for comparison, the same test was conducted on other PTC components having the same specification as the PTC components used in the production of the PTC devices. The results are shown below:
In the table, Rinitial is the initial resistance (unit: mΩ), and Imax is the maximum current (unit: Amps). The initial resistance was measured at 60° C. using Milliohm HiTester manufactured by HIOKI E.E. CORPORATION.
There was no difference that is visually determinable in the conditions of the interface between the protective member and the lead in the PTC devices A and B before and after the alkali immersion test.
In the above table, the measured results on the PTC components having the same specification as the PTC components used in the production of the PTC devices A and B (provided that, not immersed in alkali) are shown as “PTC Component 1” and “PTC Component 2”, and those immersed in the KOH aqueous solution (1N) at 60° C. for 3 months are shown as “After alkali immersion”.
“PTC Component 1” and “PTC Component 2” are the measured values as a component that has not been affected by alkali; in the PTC device A, the initial resistance values are 5.3 mΩ and 5.7 mΩ, and the initial resistance value of “After alkali immersion” is 5.5 mΩ. Thus, the resistance can be said to be substantially unchanged. Also, the Imax values are 3.366 A and 3.047 A for PTC Component 1 and PTC Component 2 respectively, and 2.979 A for “After alkali immersion”. Therefore, the Imax is also substantially unchanged. In the PTC device B, the initial resistance values for PTC component 1 and PTC component 2 are 5.5 mΩ and 5.1 mΩ, and 5.0 mΩ for “After alkali immersion”. In this case also, as in the previous case, these values can be said to be within a resistance range that is substantially unchanged. If it had been affected by immersion, it is predicted that the resistance would have increased greatly beyond the 5 mΩ range. With respect to the Imax, the values which were 3.345 A and 2.983 A for PTC Component 1 and PTC Component 2 respectively, was 3.332 A for “After alkali immersion”. Therefore, it can be also said that this is substantially unchanged.
From these results, it can be seen that the holding current property of the PTC device is substantially unaffected even if the protective member is provided around the PTC device as in the present invention.
For confirmation, the resistance-temperature (R-T) property of the PTC device A before and after the above alkali immersion experiment was measured. The result is shown in
The PTC device of the present invention can suppress the effect of electrolyte in the battery to a minimum even when disposed in the extra space within the secondary battery.
This Application is a divisional of U.S. patent application Ser. No. 13/807,699, filed Mar. 28, 2013, entitled PTC Device and Secondary Battery Having the Same, and incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 13807699 | Mar 2013 | US |
Child | 15620133 | US |