RU2575482C2 - Accumulator in film casing and method of its testing - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is referred to the sphere of electric engineering, in particular, to method for manufacturing accumulator in film casing. The accumulator in film casing (1) has accumulator cell (10) equipped with multitude of electrode plates layered through separators and outer film (40) intended for hermetic sealing of the accumulator cell (10). Filming (50) is attached to pit (51) in predetermined areas (60, 62) set at the surface of outer film (40). The predetermined areas (60, 62) are areas received by exclusion of overlapping areas (61) from projected areas obtained by projection of electrode plates to the surface of outer film (40), at that overlapping areas are the areas where projected areas are overlapped with parts (13a) placed between electrode plates at the most outer layers and outer film (40). Pit (51) at the surface may be closed without increase in thickness of the accumulator (1) in film casing.

EFFECT: decrease in total thickness of accumulators in film casing being a part of modular unit.

13 cl, 10 dwg

Description

Technical field

[0001] The present invention relates to a film-enclosed battery.

BACKGROUND OF THE INVENTION

[0002] A well-known film-enclosed battery has a battery cell and an outer film for sealing the battery cell. The outer film has at least a hot-melt binder layer, a metal layer and a protective layer.

[0003] In the manufacturing process of a film-enclosed battery with the above structure, a very small pit may occur on the surface of the battery-enclosed battery due to an external force. For example, when a battery enclosed in a film sheath is captured by a robot grip, a very small hole may appear on the surface of the protective layer of the outer film.

[0004] In order to prevent damage to or contamination of the surface of the laminated film during the manufacturing process, Patent Document 1 provides a method for manufacturing a laminated (multi-layer) battery using a laminated film with a protective film attached to the protective layer. In Patent Document 1, a protective film is pre-attached to the surface of the laminated film, the adhesive strength of which decreases due to ultraviolet radiation, and the battery enclosed in the film sheath is manufactured using the battery cell and the laminated film, and only then the protective film is removed by irradiation with ultraviolet light.

[0005] However, the above method requires a peeling process of the protective film. Assuming that a hole has already appeared on the protective layer before attaching the protective film, when the protective film is peeled off, this hole is exposed. On the contrary, assuming that in order to close the pit, the protective film remains on the surface of the laminated film, in Patent Document 1, the thickness of the battery enclosed in the film shell increases due to the protective film attached over the entire surface of the protective layer of the laminated film.

In many cases, a film-enclosed battery is used in a state where a large number of film-enclosed batteries are stacked in the directions of their thickness. Thus, even if there is a slight increase in the thickness of one battery enclosed in a film sheath, the total thickness of the batteries enclosed in a film sheath, stacked or assembled, increases significantly.

[0006] An object of the invention is to close a hole arising on a surface of a battery enclosed in a film sheath without increasing the thickness of the battery enclosed in a film sheath.

List of links

Patent documents

[0007] Patent Document 1: Japanese Preliminary Patent Publication No. 2009-043442 (A)

SUMMARY OF THE INVENTION

[0008] The film-enclosed battery of the invention has a battery cell equipped with a plurality of electrode plates laminated through separators, an outer film for sealing the battery cell, and a coating film attached to a pit present in predetermined areas defined on the surface of the outer film. Predefined regions are regions obtained by excluding overlapping regions from projected regions obtained by projecting the electrode plates onto the surface of the outer film, and overlapping regions being those regions where the projected regions overlap with parts located between the electrode plates on the outermost layers and the outer film or between electrode plates and separators.

[0009] For example, the above details include a bonding part, the ends of which are attached to the respective surfaces of the electrode plates on the outermost layers.

In one aspect of the invention, predetermined regions include a first region defined on one surface of the outer film and a second region defined on another surface of the outer film. The first region is the region obtained by excluding the first overlap region from the projected region obtained by projecting the electrode plate on the uppermost layer onto one surface of the outer film, the first overlapping region overlapping with one end of each of the bonding parts attached to one surface of the electrode plate on the uppermost layer. The second region is the region obtained by excluding the second overlap region from the projected region obtained by projecting the electrode plate on the lowermost layer onto another surface of the outer film, the second overlapping region overlapping with the other end of each of the bonding parts attached to the other surface of the electrode plate on the lowermost layer. A coating film is attached to at least one of the first region and the second region.

[0010] For example, the above details include insulating films interposed between the electrode plates and the separators. In another aspect of the invention, each of the above parts includes a bonding part, the ends of which are attached to the respective surfaces of the electrode plates on the outermost layers, and insulating films placed between the electrode plates and separators.

In addition, the plurality of electrode plates constituting the battery cell includes electrode plates, each of which has a relatively large area, and electrode plates, each of which has a relatively small area. Preferably, the electrode plates constituting (“building”) the above projected areas are electrode plates, each of which has a relatively small area.

[0011] The battery module of the invention has a plurality of film-wrapped batteries of the invention and a housing in which a plurality of film-sealed batteries are stacked. A plurality of battery-enclosed batteries are stacked along the layering direction of the electrode plates constituting the battery cell.

[0012] In a modular unit of the invention, a plurality of battery modules of the invention are stacked and the plurality of battery modules are connected to each other.

[0013] In an electric vehicle (electric vehicle) constructed according to the invention, the above modular unit according to the invention is placed under the seat of the vehicle.

[0014] In addition, the invention includes a method for checking a film-enclosed battery, the battery cell of which is equipped with a plurality of electrode plates laminated through separators and hermetically sealed with an outer film before attaching the coating film to a pit on the surface. The method has a step (process) for detecting the presence or absence of a pit on the surface of a battery enclosed in a film sheath and a step (process) for determining whether the position of the pit is in predetermined areas. The above predefined regions are regions obtained by excluding overlapping regions from projected regions obtained by projecting the electrode plates onto the surface of the outer film, wherein the overlapping regions are those regions where the projected regions overlap with parts located between the electrode plates on the outermost layers and the outer film or between electrode plates and separators.

In a further aspect of the invention, the method further includes the step of determining whether a coating film having a predetermined size for closing the pit protrudes from the predetermined areas.

[0015] According to the invention, it is possible to cover a hole that has arisen on the surface of a battery enclosed in a film sheath by a coating film attached to the surface of an outer film without increasing the thickness of the battery enclosed in a film sheath.

Brief Description of the Drawings

[0016] FIG. 1 is a perspective view illustrating the appearance of one embodiment of a film-enclosed battery.

FIG. 2 is an exploded perspective view illustrating a film-enclosed battery shown in FIG. one.

FIG. 3 is an enlarged sectional view along line III-III of FIG. one.

FIG. 4 is a schematic sectional view illustrating a laminated (multilayer) film structure.

FIG. 5 is a sectional view along line V-V of FIG. one.

FIG. 6 is a sectional view illustrating an embodiment of a battery module.

FIG. 7 is a partial cross-sectional view illustrating an embodiment of a modular unit.

FIG. 8 is a schematic view illustrating an example application of a modular unit.

FIG. 9 is a schematic view illustrating part of a production line for manufacturing a film-enclosed battery.

FIG. 10 is a flowchart illustrating a verification process of a film-enclosed battery.

Detailed Description of Embodiments

[0017] Film-wrapped battery

An embodiment created according to the invention is described below. FIG. 1 is a perspective view illustrating the appearance of a film-enclosed battery 1 of this embodiment, while FIG. 2 is an exploded perspective view. In addition, FIG. 3 is an enlarged sectional view along line III-III of FIG. 1. As shown in these figures, the film-enclosed battery 1 has a flat rectangular shape. The battery enclosed in a film sheath has a battery cell 10 and two films 41 and 42 for hermetically insulating the battery cell 10.

[0018] As shown in FIG. 2, the battery cell 10 has a plurality of rectangular electrode plates, consisting of positive electrode plates 11 and negative electrode plates 12 laminated alternately through separators 18 (see FIG. 3). The size (i.e., area) of the positive electrode plate 11 is set smaller than that of the negative electrode plate 12. Binding parts (tapes 13) are attached to two opposite walls of the long side of the battery cell 10 to bond the positive electrode plates 11 and the negative electrode plates 12 together. More specifically, the tapes 13 are attached to two points of each of the walls of the long side, respectively. Each tape 13 is attached so that it extends over the electrode plate on the uppermost layer (i.e., the negative electrode plate 12a shown in FIG. 3) and the electrode plate on the lowermost layer (i.e., the negative electrode plate 12b shown in Fig. 3) along the surface of the side wall of the battery cell 10. In other words, one end of each tape 13 is attached to the surface of the negative electrode plate 12a at the uppermost layer, while the other end of each tape 13 is attached to the surface of the negative plate 12b Foot electrode on the lower layer. Incidentally, the thickness of the tape 13 is approximately 50 μm.

[0019] A positive electrode protrusion 14 is outputted from each of the positive electrode plates 11, while a negative electrode protrusion 15 is outputted from each of the negative electrode plates 12. In addition, each of the protrusions 14 of the positive electrode is jointly connected to one end of the terminal 16 of the positive electrode, while each of the protrusions 15 of the negative electrode is jointly connected to one end of the terminal 17 of the negative electrode.

[0020] As shown in FIG. 3, the positive electrode active material is deposited on both surfaces of the positive electrode plate 11, while the active material of the negative electrode is deposited on both surfaces of the negative electrode plate 12. An insulating layer 19 is arranged between the positive electrode plate 11 and the separator 18. Specifically, in order to provide the insulating layer 19, an insulating film is laid in such a way between the positive electrode plate 11 and each of the separators 18 located on both sides of the same positive electrode plate. to cross the boundary between the region coated with the active material of the positive electrode and the protrusion 14 of the positive electrode. In other words, one end of the insulating layer 19 is laid so that it covers the end of the positive electrode active material deposited on the positive electrode plate 11, while the other end is laid so that it covers the “root” of the positive electrode protrusion 14 extending beyond the separator 18 Incidentally, the thickness of the insulating layer 19 is approximately 30 μm.

[0021] Each of the films 41 and 42 is a laminate film having the laminated (multilayer) structure shown in FIG. 4. In other words, each of the films 41 and 42 has at least a hot-meltable bonding layer (or heat-sealable layer) 43, a metal layer 44 and a protective layer 45. The hot-melt bonding layer 43 is formed of polypropylene (PP), the metal layer 44 is formed from aluminum (Al), and the protective layer 45 is formed of polyethylene terephthalate (PET). The thickness of each of the films 41-42 is approximately 120 μm, while the thickness of the protective layer 45 is approximately 20 μm. Incidentally, the thickness of each of the films 41-42 and / or the thickness of each of the layers can be appropriately changed. Additionally, the material of each of the layers is not limited to the specific implementation options shown and described here.

[0022] Returning again to FIG. 2, the films 41-42 are stacked in such a way that their hot-melt adhesive layers 43 (see FIG. 4) are arranged inwardly facing each other and that the battery cell 10 is laid vertically between them. Additionally, two opposing hot-melt binder layers 43 of the films 41-42 are thermally welded to each other. In FIG. 2, the heat-sealed region of the hot-melt binder layer 43 of each of the films 41-42 is indicated as a region with diagonal hatching. These two films 41-42, inseparably connected to each other by heat-sealing, are hereinafter referred to as “outer film 40”.

[0023] As shown in FIG. 1, one end of the terminal 16 of the positive electrode extends from one side (short side) of the outer film 40, extending beyond the outer film 40. Similarly, one end of the terminal 17 of the negative electrode extends from the other side (other short side) of the outer film 40, extending beyond its bounds.

[0024] The coating film, which is a feature of the invention, is further explained. As shown in FIG. 1-2, a coating film 50 having a thickness of approximately 50 μm is partially attached to the surface of the outer film 40. FIG. 5 shows a section taken along line V-V of FIG. 1. As shown in FIG. 5, the covering film 50 is attached to a very small hole 51 that has arisen on the surface of the protective layer 45 (see FIG. 4) of the outer film 40. The reason for the appearance of a very small hole 51 on the surface of the outer film 40 is as mentioned above.

[0025] Moreover, in order to prevent an increase in the thickness of the battery enclosed in the film casing 1, the coating film 50 is attached only in predetermined areas defined on the surface of the battery enclosed in the film casing.

[0026] These predefined areas defined based on the above purpose are described in detail below. As shown in FIG. 5, in the shown embodiment, the first region 60 is defined on the surface of the film 41, while the second region 62 is defined on the surface of the film 42. Incidentally, the first region 60 and the second region 62 are almost identical. Thus, the first region 60 defined on the surface of the film 41 is explained in detail. On the other hand, with regard to the second region 62 defined on the surface of the film 42, only the difference of the second region from the first region 60 is explained. In FIG. 1-2, the first region 60 is indicated by a dashed line.

[0027] The first region 60 defined on the surface of the film 41 is substantially identical to the projected region obtained by projecting the electrode plate (ie, the positive electrode plate 11 in FIG. 3) onto the surface of the film 41 (ie, the surface of the protective layer 45 ) The negative electrode plate 12a on the uppermost layer can be used as the projected object, but it is preferable to use the positive electrode plate 11 having a smaller size (smaller area) than the negative electrode plate 12a located on the uppermost projected object to obtain the projected area layer. This is because when the inner space of the outer film 40 is depressurized, the ends of the films 41-42 tend to bend toward the electrode, and therefore there is a risk of curvature of the ends of the negative electrode plate of a relatively large size. It is difficult to attach the coating film 50 to the curved portion.

[0028] As shown in FIG. 5, the ends 13a of the tapes 13 exist in the above projected area. Additionally, as shown in FIG. 3, a portion of each of the insulating layers 19 is present in the projected region. Therefore, as shown in FIG. 3 and 5, in the projected region, there is a level difference corresponding to the thickness of the tape 13 or the thickness of the insulating layer 19. In other words, the region (overlap region 61) of the projected region overlapping with the ends 13a of the tapes 13 or a part of each of the insulating layers 19 is higher than another area. Therefore, when the coating film 50 is attached to the overlap region 61, the thickness of the film-enclosed battery 1 tends to increase by the thickness of the coating film 50. In contrast, when the coating film 50 is attached to a different region than the overlap region 61, the thickness of the coating film 50 may be compensated by the difference in levels between the overlap region 61 and the other region.

[0029] Incidentally, the thickness of the coating film 50 is approximately 50 μm, while the thickness of the insulating layer 19 is approximately 30 μm. However, as shown in FIG. 3, insulating layers 19 are attached to both sides (upper and lower sides, i.e. two layers) of each positive electrode plate 11. For example, assuming that the insulating layers 19 are respectively attached to both sides of each of the three plates of the positive electrode 11, the thickness becomes 30 μm × (two layers) × three pieces = 180 μm. A thickness of 90 μm can be provided in the direction of the upper side of the battery, while a thickness of 90 μm can be provided in the direction of the lower side of the battery, and therefore, the thickness of the coating film 50 to 50 μm can be compensated. Therefore, there is a level difference exceeding the thickness of the coating film 50 between the overlapping region of the projected region overlapping with the insulating layers 19 and the other region.

[0030] Further, the thickness of the tape 13 and the thickness of the coating film 50 is 50 μm, and therefore, there is a level difference to compensate for the thickness of the coating film 50 between the overlap region of the projected region overlapping with the tapes 13a and another region.

[0031] Briefly, the first region 60 defined on the surface of the film 41 is the region obtained by excluding the first overlap region 61 from the projected region obtained by projecting the positive electrode plate 11 onto the film surface 41. On the other hand, the second region 62 defined on the surface of the film 42 is a region obtained by excluding the second overlap region 61 from the projected region obtained by projecting the positive electrode plate 11 onto the surface of the film 42.

[0032] From the foregoing explanation, it will be understood that in the first embodiment, the predetermined areas defined based on the above purpose are the remaining areas obtained by excluding overlapping areas overlapping with parts (tapes 13a) located between the electrode plates on the outermost layers and external film, and parts (insulating layers 19) located between the electrode plates and separators, from the projected area obtained by projecting the electrode plates on p the surface of the outer film. Incidentally, in the battery cell 10 shown in FIG. 5, some kind of parts other than the ends of the tapes 13 can be placed between the electrode plates on the outermost layers and the film 41. In this case, the overlap region of the projected region overlapping with the details of this kind is also included in the overlap region 61.

[0033] Incidentally, at least one of the electrode plate on the uppermost layer and the electrode plate on the lowest layer in the battery cell 10 may be a positive electrode plate. Even when the positive electrode plate is placed on the uppermost layer, it is preferable to use the positive electrode plate having a smaller area as the projected electrode plate constituting the projected region.

[0034] In addition, any of the tapes 13 and insulating layers 19 shown here may be excluded from the foregoing explanation that the first region 60 and the second region 62 can be enlarged by excluding any of the tapes 13 and any of the insulating layers 19.

[0035] Incidentally, the coating film 50 shown here is rectangular, but the shape of the coating film 50 is not limited to such a rectangular shape. Additionally, it is preferable that the shortest distance between the boundary of a very small pit 51 and the boundary of the coating film 50 is 5 mm or more. In addition, the coating film 50 of the illustrated embodiment has a two-layer structure consisting of an adhesive layer and a resin layer. Detachable paper is attached to the adhesive layer. When the coating film 50 is attached to the surface of the outer film 40, the peel-off paper is torn off and, therefore, the adhesive layer is exposed. However, the structure of the coating film 50 is not limited to the above structure. In addition, two or more coating films 50 may be attached to the surface of the outer film 40 without overlapping each other. In addition, a plurality of coating films that differ in size and / or thickness from each other can be used in combination.

[0036] Battery Module

Referring to FIG. 6, there is shown one example of a battery module 2 using a film-enclosed battery of the invention. In the shown battery module 2, three film-wrapped batteries 1A, 1B and 1C are enclosed in a module case 3 and combined together. The casing 3 of the module consists of a box-type housing 3a and a cover 3b. These three film-wrapped batteries 1A-1C are enclosed in the housing 3a when stacked in a stack in each other in the directions of their thickness. As a consequence, the coating films 50 are attached to the first region 60 of the film-wrapped battery of the upper section 1A and the first region 60 of the film-wrapped battery of the lower section 1C, respectively. Additionally, the coating film 50 is attached to the second region 62 of the film-enclosed middle section accumulator 1B. As for the film-enclosed batteries 1A and 1C, the thickness of the coating film 50 can be compensated for by the level difference between the first region 60 and the overlap region 61. On the other hand, with regard to the battery 1B encapsulated in a film, the thickness of the coating film 50 can be compensated for by the level difference between the second region 62 and the overlap region 61. In other words, in any of the batteries enclosed in the film sheath, there is no increase in thickness due to the attached coating film 50. Thus, the thickness (height) of the battery module 2 is identical to the thickness (height) of the battery module using the batteries enclosed in a film sheath that are not attached covering films. Thus, even in the battery module, in which the batteries enclosed in a film sheath are enclosed in a casing and stacked in the directions of their thickness, an increase in thickness does not occur at all.

[0037] modular unit

Referring to FIG. 7, one example of a modular unit 4 is shown using the battery module shown in FIG. 6. In the illustrated modular unit 4, a plurality of battery modules 2 are installed in the housing 5 in the form of a two-section package. Specifically, each battery module 2 of the upper section is mounted on each battery module 2 of the lower section. The clamping plate 6, which goes over adjacent to each other battery modules, is mounted on the cover 3a (see Fig. 6) of the battery module 2 of the upper section. The bolts 7, each of which passes through the clamping plate 6, are installed so that they also pass through the battery module 2 of the upper section, and through the battery module 2 of the lower section. In other words, the battery module 2 of the upper section and the battery module 2 of the lower section are fixed and joined together by the bolts 7 passing through them, while the adjacent battery modules are combined together by means of the clamping plate 6. Thus, a plurality of battery modules 2 are inseparably connected together. In other words, the housing 5 is optional and may be excluded.

[0038] The modular unit 4 shown in FIG. 7, used for various purposes. As an example, a modular unit is often used as the battery pack of an electric vehicle (electric vehicle). For example, as shown in FIG. 8, the modular unit 4 is stacked under the seat 9 of the electric vehicle 8. Incidentally, when a plurality of modular units 4 are stacked under the seat 9 of the electric vehicle 8, the plurality of modular units 4 can be stacked in a state on top of each other in the space formed under the seat 9. That is, the body 5 may be excluded.

[0039] By installing a modular unit in which battery modules, each having a film-enclosed battery of the invention, stacked in a stack in the directions of their thickness, stacked in a stack in the direction of the height of the electric vehicle, under the seat, it is possible to increase the structural flexibility of the interior of the vehicle in top of the seat.

[0040] Verification Method

Next, a method of manufacturing a film-enclosed battery 1 shown in FIG. 1-2. However, a detailed description of the processes common to the well-known manufacturing method is omitted. As a result of this, from the manufacturing processes of a battery-enclosed battery 1, a process for checking a battery-enclosed battery with a pit and a battery-enclosed battery without a pit is described below.

[0041] FIG. 9 is a schematic view illustrating a portion of a production line for manufacturing a film-enclosed battery 1. A battery is illustrated in FIG. 10 is a flowchart illustrating a flowchart of a verification process. As shown in FIG. 9, a common tray 70, an inspection platform 71, distribution trays 72a, 72b and 72c, determination means 73 and moving means 74 are provided on the production line. The determination means 73 consists of a camera 80, a computer 81 for processing the images photographed by the camera 80, and for determining the presence or absence of a very small hole, and a memory 82 for storing programs executed by the computer 81 and various data. Means 74 of the movement consists of a robotic arm configured to operate based on instructions from computer 81.

Each step of the flowchart of FIG. 10 is as follows.

Stage 1. Capture the battery enclosed in a film sheath 1 from the common tray 70.

Stage 2. The movement of the prisoner in a film sheath of the battery 1 on the inspection platform 71.

Stage 3. Capturing an image of a battery 1 enclosed in a film sheath on the viewing platform 71 by a camera 80.

Stage 4. Processing of the photographic image by computer 81.

Step 5. Determine whether or not a very small hole is present.

Step 6. Determine whether or not a very small hole is located in predefined areas.

Step 7. Moving to distribution tray 72a.

Step 8. Moving to distribution tray 72b.

Step 9. Moving to the distribution tray 72c.

[0042] The flowchart of the verification process is explained below with reference to FIG. 10. The common tray 70, in which a plurality of accumulators enclosed in a film sheath 1 accumulates, is transported to a predetermined position by means of a conveyance (not shown). Immediately after the common tray 70 is transported to a predetermined position, the robot arm 74 grabs any of the battery-enclosed batteries 1 from the common tray 70 (see step 1) and then moves the captured battery 1 into the film-wrapped shell to the viewing platform 71 (see step 2). After that, on the viewing platform 71, the camera 80 takes an image of the battery 1 enclosed in a film shell (see step 3).

[0043] A photographic image captured by the camera 80 is input to the computer 81, and then the input photographic image is processed by the computer 81 (see step 4). Next, the computer 81 detects or determines, based on the result of the image processing, the presence or absence of a very small pit (see step 5). Specifically, the computer 81 determines, based on the brightness information within the photographic image, the boundary (edge) of the battery 1 enclosed in a film shell and a very small pit. More specifically, within a photographic image, the brightness tends to change sharply in front and behind the image elements corresponding to the boundary of the battery-wrapped battery 1. Thus, the boundary of the battery-wrapped battery 1 can be detected by acquiring an image element whose brightness changes sharply compared with image elements adjacent to each other, and its coordinates. Furthermore, when a very small dimple is present on the surface of the battery enclosed in a film shell 1, the brightness tends to change sharply in front and behind an image element corresponding to a very small dimple. Thus, the presence or absence of a very small fossa can be detected by determining whether an image element is present or absent whose brightness changes dramatically compared to image elements adjacent to each other inside the detected boundary of the battery 1 enclosed in a film shell.

[0044] When a very small hole is detected, i. when an image element is detected whose brightness changes dramatically compared to image elements adjacent to each other, computer 81 determines whether or not a very small dimple is present in any of the above first region 60 and the above second region 62 (see step 6 ) Specifically, computer 81 is configured to obtain the coordinates of an image element corresponding to a very small pit (i.e., an image element whose brightness changes dramatically compared to image elements adjacent to each other). On the other hand, region information indicating the coordinates of the boundary of the first region 60 or the coordinates of the boundary of the second region 62 is previously stored in the memory 82. Computer 81 compares the region information read from the memory 82 with the coordinates of the image element corresponding to a very small hole , and then determines whether or not a very small hole is present in the first region 60 or the second region 62.

[0045] When it is determined in step 5 that a very small pit is missing, the film-enclosed battery 1 is moved by the robot arm 74 to the first distribution tray 72a (see step 7).

[0046] When it is determined in step 6 that a very small hole is present outside the predetermined areas, the film-enclosed battery 1 is moved by the robot arm 74 to the second distribution tray 72b (see step 8). In contrast, when it is determined in step 6 that a very small hole is present in predetermined areas, the battery 1 enclosed in the film casing is moved by the robot arm 74 to the third distribution tray 72c (see step 9).

[0047] Further, when it is determined in step 6 that a very small hole is present in predetermined areas, and therefore, the above coating film 50 is attached to a very small hole, a process can be carried out to determine if the coating film is or not 50 of the predefined areas. Specifically, size information indicating the size of the coating film 50 is previously stored in the memory 82. The computer 81 performs the above determination based on this size information and area information read from the memory 82 and coordinates indicating the center of a very small pit. In this case, the above determination is made under the assumption that the coating film 50 is attached so that the center of the coating film 50 and the center of a very small hole coincide with each other.

[0048] In addition, a symbol or sign may be printed on the surface of the film-enclosed battery 1 indicating the determination result in step 5 and the determination result in step 6. For example, an inkjet printer can be used for printing. In the event that a symbol is printed indicating the result of the determination, it is no longer necessary to distribute the film-enclosed batteries 1 on the basis of the determination into the appropriate of the various distribution trays 72a-72c.

[0049] Furthermore, the coating film can be attached to a very small pit by means of a manipulator or the like. when using the data of the detected coordinates.

Claims (13)

1. A film-enclosed battery comprising:
a battery cell equipped with a plurality of electrode plates laminated through separators;
external film for tight insulation of the battery cell; and
a coating film attached to a hole present in predetermined areas defined on the surface of the outer film and partially attached to a portion of the surface to close the hole,
wherein the predefined regions are regions obtained by excluding overlapping regions from the projected regions obtained by projecting the electrode plates onto the surface of the outer film, the overlapping regions being those regions where the projected regions overlap with a connecting part located between the electrode plates on the outermost layers and the outer film, or insulating films located between the electrode plates and separators. 2. A battery enclosed in a film sheath according to claim 1, wherein both ends of the connecting part are attached to the corresponding surfaces of the electrode plates on the outermost layers. 3. A battery enclosed in a film sheath according to claim 2, wherein:
predefined regions include a first region defined on one surface of the outer film and a second region defined on another surface of the outer film;
the first region is the region obtained by excluding the first overlap region from the projected region obtained by projecting the electrode plate on the uppermost layer onto one surface of the outer film, the first overlapping region overlapping with one end of the bonding part attached to one surface of the electrode plate on the uppermost layer;
the second region is the region obtained by excluding the second overlap region from the projected region obtained by projecting the electrode plate on the lowermost layer onto another surface of the outer film, the second overlapping region overlapping with the other end of the bonding part attached to the other surface of the electrode plate on the lowermost layer; and
a coating film is attached to at least one of the first region and the second region. 4. A battery enclosed in a film sheath according to claim 1, wherein the connecting part is not provided; and overlapping areas are determined by insulating films. 5. A battery enclosed in a film sheath according to claim 1, wherein the overlapping regions are determined both by the connecting part, the ends of which are attached to the corresponding surfaces of the electrode plates on the outermost layers, and by insulating films placed between the electrode plates and separators. 6. A battery enclosed in a film sheath according to any one of paragraphs. 1-5, wherein the plurality of electrode plates include electrode plates, each of which has a relatively large area, and electrode plates, each of which has a relatively small area; and the electrode plates constituting the projected regions are those electrode plates, each of which has a relatively small area. 7. A battery module comprising in combination:
a plurality of film-enclosed batteries according to any one of paragraphs. 1-6; and
a casing in which a plurality of battery-enclosed batteries are placed in a stacked state,
however, a plurality of batteries enclosed in a film shell are stacked along the stacking direction of the electrode plates constituting the battery cell. 8. A modular unit comprising a plurality of battery modules according to claim 7, wherein a plurality of battery modules are laid out in a stacked state and connected to each other. 9. An electric vehicle comprising a modular unit according to claim 8, wherein the modular unit is located under the vehicle seat. 10. A method of manufacturing a film-enclosed battery containing the following steps:
completing the manufacture of a battery enclosed in a film sheath by means of hermetic isolation of a battery cell equipped with a plurality of electrode plates laminated through separators with an external film;
check whether the battery enclosed in a film sheath is a battery enclosed in a film sheath with a pit in predetermined areas defined on the surface of the outer film or a battery without a pit enclosed in a film sheath in these predetermined areas; and
attach the coating film to part of the surface of the outer film, closing the hole;
wherein the verification step comprises:
detecting the presence or absence of a fossa on the surface of a battery enclosed in a film sheath; and
determining whether the position of the pit is in predefined areas,
wherein the predefined regions are regions obtained by excluding overlapping regions from the projected regions obtained by projecting the electrode plates onto the surface of the outer film, the overlapping regions being those regions where the projected regions overlap with a connecting part located between the electrode plates on the outermost layers and the outer film, or insulating films located between the electrode plates and separators. 11. The method according to p. 10, while both ends of the connecting parts are attached to the corresponding surfaces of the electrode plates on the outermost layers. 12. The method according to p. 10, while the connecting part is not provided; and overlapping areas are determined by insulating films. 13. The method according to p. 10, which further comprises determining whether a coating film having a predetermined size for closing the pit protrudes from predefined areas.

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