KR101269973B1 - battery - Google Patents

Abstract

(Problem) In a battery sealed by covering a power generating element with an outer film, a sealed part of the outer film and an electrode tab drawn out from the sealed part against various vibrations acting on the battery after battery installation; A battery that can avoid stress concentration in the vicinity of the boundary line is provided.
(Solution means) The power generating element 11 is covered by being sandwiched by a pair of exterior films 12 and 13, and the joints of the peripheral parts of the positive exterior films 12 and 13 are joined to each other. The sealing portion B of the exterior films 12 and 13 includes an electrode tab 14 for sealing the power generation element 11 between the exterior films 12 and 13 and transmitting and receiving the current from the power generation element 11. In the battery 10 withdrawn from the outside, the electrode tab 14 has a surface of the electrode tab 14 at the tip side from the boundary line L between the sealing portion B and the electrode tab 14. The pleats 17 are bent in a wave shape.

Description

Battery {BATTERY}

The present invention relates to a battery in which a power generating element is covered with an outer film and sealed.

A battery (so-called laminate cell) in which a power generating element is sealed with an outer film is used as a plurality of battery aggregates (column cells) to secure a desired output. This battery is excellent in heat dissipation because it is thin and has a large surface area. Further, since the battery assembly is compact, for example, a laminated battery in which batteries are stacked in multiple stages, and electrode tabs of batteries adjacent to each other in the stacking direction are laminated and connected. As a secondary battery, it is used as a secondary battery for electric vehicles or a hybrid electric vehicle.

However, when constituting this type of battery stack assembly, the electrode tab drawn out from the battery outer film of the battery is bent to form a structure in which the front end portions of the electrode tab are laminated and bonded, so that the outer film peripheral portion is formed. ), The bending stress of the electrode tab was concentrated in the (sealing portion), and there was a fear of breakage of the electrode tab in the vicinity of the sealing portion of the exterior film and a decrease in the sealability of the sealing portion of the exterior film. For example, Patent Document 1 discloses a battery capable of solving such a problem.

As shown in FIG. 4, the battery 50 of patent document 1 arrange | positions the flat laminated electrode 51 as a power generating element in the center part of the laminated films 52 and 53 as a pair of exterior film, The laminates 52 and 53 are covered by sandwiching both surfaces of the laminated electrode 51 with each other interposed therebetween, and the sealing portion B is formed by joining the peripheral portions of the laminate films 52 and 53 by thermal welding. The electrolyte solution is sealed together with the laminated electrode 51 between these laminate films 52 and 53.

The stacked electrode 51 is formed by sequentially stacking a plurality of positive electrode plates and negative electrode plates through separators, and each of the positive electrode plates is disposed through a positive electrode lead. While each negative electrode plate is connected to a tab (electrode tab) 54, each negative electrode plate is connected to a negative electrode tab (electrode tab) 55 through a negative electrode lead, and these positive electrode tab 54 and negative electrode tab 55 are laminated film ( 52, 53 are drawn out and exposed to the outside from the sealing part B. As shown to FIG. The electrode tabs 54 and 55 are also at the tip side from the boundary line L between the electrode tabs 54 and 55 and the sealing portion B of the laminate films 52 and 53 and the tip ends of the electrode tabs 54 and 55. On the base end side, slits 56 are formed along the extraction direction of the electrode tabs 54 and 55. As a result, a flexible portion 57 having a lower rigidity than that of other portions is formed on the front end side of the sealing portion B of the electrode tabs 54 and 55.

When the batteries 50 are stacked in a plurality of stages and the front ends of the positive electrode tabs 54 and the front ends of the negative electrode tabs 55 are laminated and bonded together, the electrode tabs 54 and 55 are bent. In particular, in the battery 50 at the uppermost stage, the electrode tabs 54 and 55 are largely bent, and as a result, bending stress may be concentrated near the boundary line L. However, in the battery 50, since the weak portion 57 is formed at the distal end side from the boundary line L of the electrode tabs 54 and 55, as described above, the stress concentration in the vicinity of the boundary line L is concentrated. Can be dispersed. Thereby, the breakage of the electrode tabs 54 and 55 in the boundary line L and the fall of the sealing property of the sealing part B of a laminated film can be avoided.

Japanese Laid-Open Patent Publication No. 2004-87300

The battery 50 described above disperses the concentration of bending stress in the vicinity of the boundary line L between the sealing portion B of the laminate film and the electrode tabs 54 and 55 when the battery stack assembly is constituted. Is effective. However, after the battery 50 is installed, with respect to various vibrations acting on the battery 50, depending on the combination of the direction, amplitude, and period of the vibration, the electrode tabs 54 and 55 are described as follows. Absorption by vibration may become inadequate, and stress concentration in the boundary line L vicinity may not be fully relaxed.

For example, each of the electrode tabs 54, 55 is each electrode tab 54, 55 by vibration (longitudinal vibration) acting in a direction perpendicular to the surfaces of the electrode tabs 54, 55. In the case where the tensile stress acts on the distal end portion, the length of the electrode tabs 54 and 55 in the extraction direction hardly changes. Therefore, the tensile stress which acts on the front-end | tip part of each electrode tab 54, 55 is transmitted to boundary line L, without attenuating in each electrode tab 54, 55. FIG. Accordingly, there is a possibility that the tensile stress is concentrated near the boundary line L. FIG.

In addition, each electrode tab 54, 55 has a substantially planar rectangular shape of the electrode tabs 54, 55 with respect to vibration (lateral vibration) acting in a direction parallel to the boundary line L. FIG. Does not change. Therefore, the vibration which acts on the front-end | tip part of each electrode tab 54, 55 in parallel with boundary line L is transmitted to boundary line L, without attenuating in each electrode tab 54, 55. As shown in FIG. Accordingly, there is a possibility that the shear stress is concentrated near the boundary line L. FIG.

In addition, since a secondary battery for an electric vehicle or a hybrid electric vehicle requires a battery stack assembly having a high output and a high capacity, the battery 50 tends to be larger in the future, and as the battery 50 becomes larger, The stress concentration in the vicinity of the boundary line L tends to occur.

This invention is made | formed in view of the said situation, In the battery which coat | covered and sealed the power generation element with the exterior film, it is external from the sealing part of this exterior film and this sealing part with respect to the various vibrations which act on a battery after battery installation. An object of the present invention is to provide a battery capable of avoiding stress concentration in the vicinity of a boundary line with an electrode tab drawn out.

Hereinafter, each means suitable for solving the said subject is demonstrated, adding an effect and the like as needed.

(1) The battery of the present invention covers the power generating element with a pair of exterior films sandwiched between them, and seals the power generating element between both the exterior films by joining the peripheral portions of the exterior films. In a battery in which an electrode tab for transmitting and receiving a current from the power generating element is taken out from a sealed portion of the exterior film to the outside, the electrode tab is disposed at a distal end side from a boundary between the sealed portion and the electrode tab. And a corrugated portion in which the surface of the electrode tab is bent in a wave shape.

According to such a structure, the electrode tab is equipped with the corrugation part by which the surface of the electrode tab was bent in the wave shape in the front end side from the boundary line between a sealing part and an electrode tab. By the wrinkles, the surface of the electrode tab can be easily curved, and the lead length of the electrode tab changes. Here, the extraction length of the electrode tab can also be changed so that the lengths of both ends parallel to the extraction direction of the electrode tab become uneven lengths. As a result, all of the bending stress, tensile stress, compressive stress, and shear stress transmitted from the distal end side of the electrode tab to the boundary line between the sealing portion and the electrode tab are alleviated.

Therefore, against the various vibrations acting on the battery after the battery is installed, the vibration can be absorbed at the pleats, and stress concentration in the vicinity of the boundary between the sealed portion and the electrode tab can be avoided. Needless to say, the wrinkle part has a high effect of absorbing vibration (vertical vibration) acting in a direction perpendicular to the surface of the electrode tab. In addition, the wrinkle part is in a direction parallel to the boundary between the sealing part and the electrode tab. It is also possible to absorb the vibrations (lateral vibrations) that act.

Thus, for example, even when the battery is employed as a secondary battery for an electric vehicle exposed to a severe vibration environment, breakage of the electrode tab near the sealing portion of the exterior film and degradation of the sealing portion of the exterior film are avoided. can do.

(2) In the battery of the present invention, preferably, at least one of both surfaces of the electrode tab is formed with a moisture resistant insulating coating film covering the boundary line between the sealing portion and the electrode tab.

According to such a structure, since the moisture proof insulating coating film is formed so that the boundary line of a sealing part and an electrode tab may be covered, the sealing property of the sealing part of an exterior film can be made more reliable.

The moisture resistant insulating coating film is a coating film formed by the moisture resistant insulating coating film. As the moisture resistant insulating coating material, various resin-based elastic paints and various rubber-based elastic paints can be used.

(3) In the battery of the present invention, preferably, the moisture resistant insulating coating film exhibits elasticity that can follow the deformation of the wrinkle portion, and the wrinkle portion is formed at the boundary between the sealing portion and the electrode tab. Cover between

Since the stiffness of the electrode tab is reduced by forming the wrinkles in the electrode tab, when the self weight of the battery and the inertial force acting on the battery are large, it may be difficult to stably hold the battery. .

Here, according to the structure of this invention, the moisture proof insulating coating film which shows elasticity which covers a wrinkle part is formed in at least one surface of both surfaces of a wrinkle part. The moisture resistant insulating coating film acts to reinforce the rigidity of the wrinkle portion, to follow the deformation of the wrinkle portion and to elastically return the deformation of the wrinkle portion. Therefore, according to the structure of this invention, it becomes possible to hold | maintain a battery more stably.

(4) In the battery of the present invention, preferably, the moisture resistant insulating coating film is a resin coating film.

According to such a structure, since a moisture proof insulating coating film is formed of the resin coating film which is cheaper than a rubber coating film, it becomes possible to manufacture a battery more cheaply.

According to the present invention, in a battery in which a power generating element is covered with an outer film and sealed, the battery is sealed between the sealing part of the outer film and the electrode tab drawn out from the sealing part against various vibrations acting on the battery after battery installation. An electrode capable of avoiding stress concentration in the vicinity of the boundary line can be provided.

1 is a side view schematically illustrating a stacked assembly of a battery of this embodiment.
Fig. 2 is an explanatory diagram schematically illustrating the battery of the present embodiment, in which Fig. 2 (a) is a top view and Fig. 2 (b) is a side view.
It is sectional drawing cut | disconnected by the AA line in FIG.2 (a).
4 is an explanatory diagram schematically illustrating a conventional battery, in which FIG. 3 (a) shows a top view and FIG. 3 (b) shows a side view.

(Mode for carrying out the invention)

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the battery of this invention is described in detail, referring drawings.

1 is a side view schematically illustrating the stacked assembly of the battery of the present embodiment. 2 is an explanatory diagram schematically illustrating the battery of the present embodiment. 2 (a) shows a top view of the battery, and FIG. 2 (b) shows a side view of the battery. 3 is sectional drawing cut | disconnected by the A-A line | wire in FIG.2 (a). Although FIG. 3 only shows the cross section by the positive electrode side of the battery of this embodiment, the negative electrode side also has substantially the same structure as the positive electrode side.

As shown in FIG. 1, the battery laminated assembly 1 laminates | stacks the battery 10 in multiple stages, and laminates and connects the electrode tabs 14 and 15 of each battery 10. As shown in FIG. As shown in FIG. 1, the stacking direction of the battery 10 is the mainstream, but may be stacked in the horizontal direction. In addition, in this embodiment, although the battery 10 forms the battery laminated assembly 1 by parallel connection, you may form the battery assembly 1 by connecting the batteries 10 in series. The battery stack 1 is placed in a case not shown, for example, and is connected to an input / output terminal (not shown) via a bus bar 2 as wiring. In addition, the assembled battery is not limited to one battery stack assembly 1 as in the present embodiment, and the plurality of battery stack assemblies 1 are connected in series, in parallel or in series by wiring such as a bus bar 2. The parallel connection is also included.

As shown in FIG.2 and 3, each battery 10 which comprises the battery laminated assembly 1 has the laminated film 11 as a pair of exterior film as the laminated electrode 11 of the flat shape as a power generating element. ), The laminate is covered by sandwiching both sides of the laminated electrode 11 by the laminate films 12 and 13, and the periphery of the laminate films 12 and 13 are joined by heat welding to close the sealed portion. (B) is formed and the electrolyte solution is sealed together with the laminated electrode 11 between these laminate films 12 and 13.

The laminated electrode 11 is a stack of a plurality of positive electrode plates 11a and negative electrode plates 11b sequentially stacked with the separators 11c interposed therebetween, and each of the positive electrode plates 11a is disposed through the positive electrode leads 11d. While connecting to the positive electrode tab (electrode tab) 14, each negative electrode plate 11b is connected to the negative electrode tab (electrode tab) 15 via a negative electrode lead (not shown), and these positive electrode tab 14 and negative electrode tab (15) is drawn out from the sealing part B of the laminated films 12 and 13, and is exposed. The positive electrode tab 14 and the negative electrode tab 15 can be formed of metal foil such as Al, Cu, Ni, Fe, etc. In the present embodiment, the positive electrode tab 14 is formed of Al and the negative electrode tab 15. It is formed of Ni-plated Cu (bonding material of Ni and Cu).

The thermoplastic resin sheet 16 is wound around the base end of the positive electrode tab 14 and the negative electrode tab 15. The resin sheet 16 is softened at the time of thermal welding of the laminate films 12 and 13, thereby ensuring the sealing property of the sealing portion B in the positive electrode tab 14 and the negative electrode tab 15. .

In the electrode tabs 14 and 15 of the present embodiment, the electrode tabs 14 and 15 are also at the tip side from the boundary line L between the sealing portions B of the laminate films 12 and 13 and the electrode tabs ( At the proximal end from the distal end portions 14 and 15, wrinkles 17 are formed in which the surfaces of the electrode tabs 14 and 15 are bent in a wave shape in a direction parallel to the boundary line L. As a result, a weak portion having rigidity lower than that of other portions is formed on the tip side of the sealing portion B of the electrode tabs 14 and 15.

Moreover, the resin coating film (moisture-resistant insulating film) 18 which exhibits elasticity, covers the wrinkle part 17, and is formed in both surfaces of the wrinkle part 17 of the electrode tab 14,15. The resin coating film 18 is formed so as to cover the entire surface of the corrugation portion 17 and cover the boundary line L between the electrode tabs 14 and 15 and the sealing portion B of the laminate films 12 and 13. . The resin coating film 18 is a coating film formed of the resin-based elastic paint, and the rigidity of the pleats 17 is reinforced by the resin coating film 18.

As the resin-based elastic coating material for forming the resin coating film 18, for example, a moisture resistant insulating coating applied to a printed circuit board of an electronic component or a wiring of an FDP (flat panel display) can be used. For example, as a moisture-resistant insulating coating film for FDP, the coating film by UV curable resin of viscoelastic 20 Mpa, coating film thickness of 300-700 micrometers, and moisture permeability of 25 g / m <2> may be formed.

According to this structure of this embodiment, the electrode tabs 14 and 15 are in the front end side from the boundary line L between the sealing part B of the laminated films 12 and 13, and the electrode tabs 14 and 15, The surface of the electrode tabs 14 and 15 is provided with the wrinkle part 17 bent in a wave shape. The wrinkles 17 allow the surfaces of the electrode tabs 14 and 15 to be easily bent, and the lead lengths of the electrode tabs 14 and 15 change. Here, the withdrawal lengths of the electrode tabs 14 and 15 vary so that the lengths of the end portions 14a, 14b, 15a and 15b parallel to the withdrawal direction of the electrode tabs 14 and 15 become uneven lengths. It is possible. For example, it is also possible to change so that the length of each end 14a, 15a increases, and the length of each end 14b, 15b decreases.

Accordingly, all of the bending stress, tensile stress, compressive stress, and shear stress transmitted from the front end side of the electrode tabs 14 and 15 to the boundary line L between the sealing portion B and the electrode tabs 14 and 15. Is relaxed.

Therefore, against the various vibrations acting on the battery 10 after the battery 10 is installed, the wrinkles 17 absorb the vibrations, and the boundary line L between the sealing portion B and the electrode tabs 14 and 15 is applied. ) Stress concentration in the vicinity can be avoided. Needless to say, the wrinkle portion 17 has a high effect of absorbing vibrations (longitudinal vibrations) acting in the direction perpendicular to the surfaces of the electrode tabs 14, 15. The vibration (lateral vibration) acting in the direction parallel to the boundary line L between the sealing portion B and the electrode tabs 14 and 15 may be absorbed.

Thus, for example, even when the battery 10 is employed as a secondary battery for an electric vehicle or a hybrid electric vehicle exposed to a severe vibration boundary, the electrode near the sealing portion B of the laminate films 12 and 13 is used. The damage of the tabs 14 and 15 and the fall of the sealing property of the sealing part B of the laminated films 12 and 13 can be avoided.

Here, according to the structure of this embodiment, the resin coating film 18 is formed so that the boundary line L between the electrode tabs 14 and 15 and the sealing part B of the laminated films 12 and 13 may be covered. Therefore, the sealing property of the sealing part B of the laminated films 12 and 13 can be made more reliable.

However, since the stiffness of the electrode tabs 14 and 15 is reduced by forming the pleats 17 on the electrode tabs 14 and 15, the self weight of the battery 10 and the inertial force acting on the battery 10 are large. In this case, it is difficult to hold the battery 10 stably.

Here, according to the structure of this embodiment, the resin coating film 18 which exhibits elasticity while covering the wrinkle part 17 on both surfaces of the wrinkle part 17 is formed. This resin coating film 18 acts to reinforce the rigidity of the pleats 17, to follow the deformation of the pleats 17, and to elastically return the deformation of the pleats 17. Therefore, according to the structure of this embodiment, it becomes possible to hold | maintain the battery 10 more stably.

Moreover, since the resin coating film 18 used as a moisture resistant insulating coating film is a moisture resistant insulating coating film which is cheaper than the rubber coating film which shows elasticity, it becomes possible to manufacture the battery 10 more inexpensively.

In addition, the battery of this invention is not limited to embodiment mentioned above, In the range which does not deviate from the summary of this invention, it can carry out in the various forms which implemented the change, improvement, etc. which a skilled person can make. Needless to say.

For example, the shape of the wrinkle part 17 shown to FIGS. 1-3 of this embodiment is only an example, The number of bending of the wrinkle part 17, bending pitch, and bending height (high and low points of difference) Can be appropriately set by the designer.

In addition, in this embodiment, although the resin coating film 18 which shows elasticity is formed in the both surfaces of the electrode tabs 14 and 15, the resin coating film 18 is only in one surface of both surfaces of the electrode tabs 14 and 15. In addition, in FIG. May be formed. In addition, although the resin coating film 18 is formed so that the wrinkle part 17 and the boundary line L may be covered, the resin coating film which covers the boundary line L without forming the resin coating film 18 in the wrinkle part 17 ( 18) may be formed only. Moreover, it is also possible to set it as the structure in which the resin coating film 18 is not formed in the electrode tab 14,15.

In addition, in this embodiment, although the resin coating film 18 which shows elasticity is formed as a moisture proof insulating coating film, the rubber coating film by a rubber type elastic paint can also be formed as a moisture proof insulating coating film.

10: Battery
11: laminated electrode (power generation element)
12, 13: laminate film (exterior film)
14: positive electrode tab (electrode tab)
15: negative electrode tab (electrode tab)
17 wrinkles
18: resin coating film (moisture resistant insulating coating film)
B: sealing part
L: Boundary Line

Claims (5)

The power generating element is covered with a pair of exterior films sandwiched between them, and the power generating elements are sealed between both the exterior films by joining the peripheral portions of the exterior films. In a battery in which an electrode tab for transmitting and receiving a current from a power generation element is drawn out from a sealed portion of the exterior film,
The electrode tab has a corrugated portion in which a surface of the electrode tab is bent in a wave shape at a front end side from a boundary between the sealing portion and the electrode tab,
At least one surface of both sides of the electrode tab covers the boundary line between the sealing portion and the electrode tab and further covers the wrinkle portion from the boundary line to follow the wrinkle portion to cover the wrinkle portion. Iii) A battery comprising an insulating coating film. delete delete The method of claim 1,
The moisture resistant insulating coating film is a resin coating film. The method according to claim 1 or 4,
The moisture resistant insulating coating film reaches the outer surface of the outer film.

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