Source: https://patents.google.com/patent/DE102009032523A1/en
Timestamp: 2020-04-04 13:21:25
Document Index: 356357806

Matched Legal Cases: ['arts 3', 'art 3', 'arts 3', 'art,\n2', 'arts 3', 'art 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'art 3', 'art 3', 'art 3', 'art 3', 'arts 3', 'arts 3', 'arts 3', 'art 3', 'arts 3', 'art 3', 'art 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3', 'arts 3']

DE102009032523A1 - Method for producing an electrochemical cell - Google Patents
Method for producing an electrochemical cell
DE102009032523A1
DE102009032523A1 DE200910032523 DE102009032523A DE102009032523A1 DE 102009032523 A1 DE102009032523 A1 DE 102009032523A1 DE 200910032523 DE200910032523 DE 200910032523 DE 102009032523 A DE102009032523 A DE 102009032523A DE 102009032523 A1 DE102009032523 A1 DE 102009032523A1
DE200910032523
2009-07-10 Application filed by Li Tec Battery GmbH filed Critical Li Tec Battery GmbH
2009-07-10 Priority to DE200910032523 priority Critical patent/DE102009032523A1/en
2011-01-20 Publication of DE102009032523A1 publication Critical patent/DE102009032523A1/en
A method of making an electrochemical cell (1), the electrochemical cell (1) comprising at least one electrode stack received within a sheath (2), the sheath (2) being formed from at least two sheath parts (3) Cladding parts (3) each have at least one seam surface (5) on which the cladding parts (3) are at least partially engageable with one another, comprising the following method steps: attaching a defined amount of additional sealing means (9) at least indirectly to a limited section (8 ) the seam surface (5) of at least one of the covering parts (3); Applying the seaming surface (5) of one of the wrapping parts (3) to the seaming surface (5) of another of the wrapping parts (3); Then applying heat to the seam surfaces (5).
The The present invention relates to a method for producing a electrochemical cell.
From the DE 600 04 118 T2 For example, a method of manufacturing an electrochemical cell is known. The electrochemical cell comprises contact tabs which establish an electrical connection between the cell interior and the cell exterior. The cell housing is formed in two parts and has an upper sealing layer and a lower sealing layer, each of which forms a laminate-like structure for sealing the electrochemical cell along sealing grooves. The sealing layers have at least three layers, wherein a polymer layer, a metal layer and an adhesive layer are provided. The lobes act as barriers between the adhesive layers and prevent the formation of an optimal hermetic seal between these layers. For better sealing in the region of the contact tabs, a pretreatment of the contact tabs is made before closing the cell housing. In this case, resin films are molded onto the contact tabs.
electrochemical Cells have as an important functional element current conductors, the the electrical energy from the electrodes inside the electrochemical Lead the cell outwards. A good seal between current conductors and electrochemical cladding Cell is required, otherwise material from the battery cell interior, in particular electrolyte material or reaction products of the electrolyte, can step outside. For lithium-ion cells the sealing is particularly important because of penetrating moisture irreversibly damage the electrochemical cells or can render useless.
For the cladding of an electrochemical cell may be a composite foil which is a metal layer, in particular an aluminum layer may include. The composite film usually has on its Inside a heat-sealable polymer layer. This layer can have a cross-sectional thickness of well below 100 μm exhibit. When closing the electrochemical cell becomes a good adhesive by a suitable heat sealing tool Achieved connection between the sealing layers of two composite films. When sealing to the arresters, however, note that the adhesion of the sealing layer to the metal of the current conductor is sufficiently stable and despite the chemical action of the in Electrolyte cell used a fuse obtained against detachment of the sealing layer to the current collector remains.
in principle the sealing in the area of the current conductors requires a special Attention, especially if the composite film is a relatively thin Polymer layer as a sealing layer, which thickness differences can not compensate reliably on the arrester. There a Current conductor optionally a layer thickness of more than 0.2 mm is basically the risk that in the area of the current conductor gaps in the enclosure form, which lead to leaks in the electrochemical cell can.
1 shows a detail of an electrochemical cell according to the prior art. In it is a detail of the wrapping 2 an electrochemical cell 1 shown, which consists of two wrapping parts 3 is formed. Each serving part 3 has a circumferential seam section 4 on, with the two enclosure parts 3 mostly at seam surfaces 5 of the seam section 4 are in contact with each other. In one area of the current collector feedthrough 6 extends a current collector 7 through the serving 2 therethrough. The envelope nestles when closing to the current conductor 7 so that in the area of the current collector feedthrough 6 Steps at the seams can result.
It The object of the present invention is a method for producing to provide an improved electrochemical cell. These The object is achieved by a method according to claim 1.
The electrochemical cell to be produced comprises at least one electrode stack, which is accommodated within an enclosure of the electrochemical cell. In this case, the casing has at least two casing parts, the casing parts each having at least one seam surface on which the casing parts can at least partially be brought into contact with one another. When manufacturing the electrochemical cell, a defined amount of additional sealing agent is at least indirectly applied to a limited portion of the seam surface of at least one of the covering parts. Further, the seaming surface of one of the wrapping parts is applied to the seaming surface of one of the other wrapping parts. The attachment of the defined amount of additional sealant to the seam surface can either be done prior to the application of the seam surface of one of the jacket parts to the seam surface of one of the other jacket parts or simultaneously. When attached at the same time the defined amount of additional sealant is attached at the same time to the seam surfaces of two or more wrapping parts. After that, after a defined amount of additional sealant has been applied to the seaming surface of at least one of the wrapping parts, and after the seaming surface of one of the wrapping parts has been attached to the seaming surface of another of the wrapping parts Heat is applied to the seam surfaces. By applying heat, a sealing of the abutted seam surfaces of the different covering parts can take place. Furthermore, a sealing of the seam surfaces with the defined amount of additional sealing agent with the seam surface can take place. For this purpose, heat is preferably applied to the respective point to be sealed to the extent that the respective areas to be sealed are heated to a temperature which is greater than the respective melting temperatures of at least one material on the sections to be sealed.
By the application of additional sealant may seal the enclosure improved, especially in areas of the enclosure, the increased stress, in particular an increased mechanical stress, are exposed, or in areas due to their geometric shape by means of the envelope can only be sealed inadequately reliable.
Under Additional sealant may be understood as a material which is suitable, a material connection between different components, in particular different covering parts, manufacture. The additional sealant can be used to seal at least portions of gaps between the sheath parts serve.
Under a defined amount of additional sealant is in particular to understand such an amount as necessary and / or at least useful for improved sealing of an area of the Serving can be considered. Under a limited Section of the interface is within the scope of the present invention in particular, to understand a section that is not in particular extends to the entire seam surface. The scope of the limited In particular, the section is at most half the seam surface, in particular a maximum of ¼ of the seam surface, in particular, at most 10% of the suture surface. In particular, extends the limited section extends to an area of the seam surface, which in particular due to the geometric conditions and / or the mechanical stress increases to a gap formation, that is, a formation of leaks in the seam area, can tend. The limited section may in particular be one Section of the suture surface that is to abut with a provided the sheath penetrating current conductor is. Furthermore, the demarcated area may be a portion of the aforementioned Be section.
in the Meaning of the invention is under an electrochemical cell a Device to understand which also at least one electrode stack includes. The electrochemical cell also includes a sheath that faces the electrode stack an environment of the electrochemical cell gas and liquid-tight seals. Usually, at least one current conductor provided, which extends from the enclosure.
in the According to the invention, a device is under an electrode stack to understand which as an assembly of a galvanic cell too the storage of chemical energy and the release of electrical energy serves. Before the release of electrical energy is stored chemical Energy converted into electrical energy. During the store is supplied to the electrode stack or the galvanic cell electrical energy converted into chemical energy and stored. For this purpose, the electrode stack has several layers, at least an anode layer, a cathode layer and a separator layer. The layers are stacked or stacked, wherein the separator layer is at least partially between an anode layer and a cathode layer. Preferably repeated this sequence of layers within the electrode stack multiply. Preferably, some electrodes are in particular electrical with each other connected, in particular connected in parallel. Preferably, the layers are wound up into an electrode winding. Subsequently, the term "electrode stack" for Electrode winding used.
Under Envelope is at least partially within the scope of the invention Limitation to understand which the electrode stack to the outside delimited. The envelope is preferably gas and liquid-tight, so that a material exchange with the environment does not take place can. The electrode stacks are inside the enclosure arranged. At least one current conductor, in particular two current conductors extend out of the envelope and serve for Connecting the electrode stacks. The outward extending current collector preferably make the Positive pole connection and the negative pole connection of the battery cell. However, there may be several current conductors from the enclosure extend, in particular four current conductors. When the battery cell it has two electrode stacks connected in series with each other are, so are two electrodes of different electrode stack connected with each other.
A current collector is an element which is made of an electrically conductive material. It is used to conduct electricity between two geometrically separated points. In the present case, a current collector is connected to an electrode stack. Preferably, the current conductor is connected to all the same electrodes of an electrode stack, ie either with the cathodes or with the anodes. It is self-ver It is obvious that a current collector is not connected to the cathodes and anodes of an electrode stack at the same time, as this would lead to a short circuit. However, a current collector may be connected to different electrodes of different electrode stacks, such. B. in a series connection of the two electrode stack. At least one current conductor extends from the enclosure and can serve to connect the battery cells to the outside. The current collector may be integrally formed with one or more electrodes. A distinction between current collector and electrode can be seen in that the current conductor is not coated in particular with active electrode material.
Preferably can the additional sealant during the application of Heat change its shape. That's it the additional sealant preferably of a meltable Material, in particular made of a polymer material. By the change of shape during the application of heat the additional sealant may preferably in cohesive Contact with the seam surface of at least one of the covering parts, in particular advised both enclosure parts. It can preferably a nestling of the additional sealant to the Contour of the seam surface result. Furthermore, can also be a Nestling of the seam surface to the additional sealant result. This can result in an improved sealing effect of the envelope in the limited section of the suture surface.
Preferably the seam surfaces are directly on one of the sheath parts arranged. In this case, the wrapping parts directly with another component in the plant and to the immediate Seam surfaces arranged on the wrapping parts be connected to each other gas and / or liquid-tight.
alternative For this purpose, the seam surface at least on the limited section at least partially at a separate to the enclosure part Be arranged pre-seal. The presealing element is at least assigned to one of the enclosure parts and then provides the Seam surface ready for this cladding part. The Pre-sealing element itself may in turn preferably sealingly be connected to the cladding part. The presealing element may preferably be in the form of a presealing film. The presetting element can each be a single enclosure part be assigned. Furthermore, the pre-seal can also at the same time be associated with two enclosure parts. In this case For example, the presealing element may be the seam surfaces of both casing parts at least partially provide. In this case, the pre-seal element at least after its complete manufacture or arrangement have a recess on the enclosure parts. By Such a recess can in particular be passed through a current conductor become. The contact surface of the pre-seal on the current conductor provides in such an application, the seam area at least one wrapping part. The separate pre-sealing element is in a further process step with at least one of Enclosed parts connected, preferably firmly connected. It can also come with two serving parts get connected.
In a preferred embodiment are in the limited Section the seam surfaces of at least two wrapping parts together on a separate presealing element, in particular one Pre-seal foil, arranged. This is a current collector together with the additional sealant of the pre-seal element at least partially enclosed. Then the current collector is connected with the presetting element in contact with at least one of the covering parts brought. Then the current collector is connected with the additional sealant and the pre-seal in contact with brought to the other of the wrapping parts. The presealing element may, but need not, be integrally formed. Especially the presealing element may be formed in two pieces. The presealing element may be made of a presealing film, which wrap like a tape around a current conductor around leaves. But the pre-seal can also be made of two or made of several separate sections of a Vorsiegelfolie be. In this case, a portion of the Vorsiegelfolie first on one side of the current conductor, in particular on a discharge side, to be ordered. Subsequently, another section the Vorsiegelfolie on the other side of the Stromableiters, in particular the other Ableiterbreitseite attached. At the trailing edges, the overlaps overlap respective sections of the Vorsiegelfolie the current conductor. there The separate Vorsiegelfolien can each other in plant advised to be sealed and sealed together. In such a Embodiment are the seam surfaces, the in this case, by the surfaces facing the current conductor are formed of the pre-seal element, already in contact with the current collector or with a respective other wrapping part assigned Seam surface before the cladding itself in plant with the pre-seal element.
Preferably, the seam surfaces and the additional sealing means are made of a similar material, in particular of an identical material. By two similar materials are meant in particular such material combinations, between which in principle a cohesive connection without the addition of further separate adhesive or connecting means is possible. In the preferred use of a identical material for the seam surfaces and for the additional sealant, in particular polymer-based, the cohesive connection can be made cheap and reliable.
Preferably the seam surface has an uneven surface at the limited portion Contour on. Basically, the seam surface at least mostly arranged in one plane be. For sections of the suture surface resulting from this Protrude level, so at least partially an uneven Contour can have special quality requirements the seal. Especially on such uneven Contours of the seam surfaces are favorable when the electrochemical cell by means of a method described above is prepared using an additional sealant.
Preferably the additional sealant is at least indirectly investing in a Current conductor, in particular to a Ableiterschmalseite a Stromableiters brought. Under Ableiterschmalseite is a lateral boundary surface of the current conductor in the area of the arrester bushing, which is smaller than another side of the current conductor in this Area. The other, wider side of the current collector is called Ableiterbreitseite called. The seam area is at least mostly arranged in a plane, which aligned parallel to Ableiterbreitseite. Therefore, it can become in the area of the arrester narrow side give a step, which by a seal is preferably compensate. If the additional sealant is at least indirectly in contact with the Ableiterschmalseite can the additional sealant to compensate for this level, and in particular a steady guiding of the seam area in the area favor the arrester narrow side. Edged and / or stepped Formations of the seam surface can thus be reduced or avoided.
Further Advantages, features and applications of the present Invention will become apparent from the following description in conjunction with the figures. It shows:
1 Sectionally the sealing area in the region of the current collector leadthrough of an electrochemical cell according to the prior art,
2 1, in detail, the sealing region in the region of the current conductor feedthrough of an electrochemical cell produced according to the invention in a first embodiment,
a) before the heat treatment,
b) after the heat treatment;
3 a detail of the sealing region in the region of the current conductor feedthrough of an electrochemical cell produced according to the invention in a second embodiment after the heat treatment;
4 two arranged on a Vorsiegelfolie current conductor with additional sealant in plan view before the heat treatment;
5 an arranged between two Vorsiegelfolienabschnitten current conductor with additional sealant in side view before the heat treatment;
6 a arranged between two Vorsiegelfolienabschnitten current conductor with additional sealant in a perspective view before the heat treatment;
7 an arranged between two Vorsiegelfolienabschnitten current conductor with additional sealant in a perspective view after the heat treatment.
2 shows a section of a seam section 4 an electrochemical cell 1 during the production process according to the invention. The electrochemical cell 1 has an envelope 2 on, with the wrapping 2 from two separate wrapping parts 3 is formed. Each serving part 3 is a laminated molded article made from a multilayer composite film by means of a deep drawing process. At respective seam surfaces 5 of the seam section 4 lie the two wrapping parts 3 to each other.
In one area of the current collector feedthrough 6 in which there is a current collector 7 through the serving 2 from an interior of the electrochemical cell 1 extends outwards, is between the seam surfaces 5 the two wrapping parts 3 a current collector 7 arranged so that the seam surfaces 5 the two wrapping parts 3 in the area of the current collector feedthrough 6 do not lie directly against each other. The current collector 7 has a rectangular cross-section with a discharge narrow side 10 and a discharge broadside 11 , wherein the arrester narrow side 10 smaller than the Ableiterbreitseite 11 , The trailing narrow sides 10 and the Ableiterbreitseiten 11 extend through the cladding 2 therethrough. The seam surfaces 5 are each arranged in a plane E, wherein in the region of the arrester lead-through the seam surface 5 sticking out of the E plane. The Ableiterbreitseite 11 is aligned parallel to the plane E. The arrester narrow side 10 is aligned perpendicular to the plane E. In a transition section has the seam surface 5 an uneven outline.
It is in 2a) to recognize that in the field of current collector implementation 6 laterally to the Current conductor 7 a defined amount of additional sealant is attached. This defined amount of additional sealant 9 will only be in the area of the uneven contour of the suture surface at the suture surfaces 5 both enclosure parts 3 appropriate. The region of the uneven contour represents the limited section in the sense of the present invention, wherein the delimitation of the limited section is fluid and can not be accurately retained by means of geometric fixed points of the enclosure parts. The attachment of the defined amount of additional sealant 9 can during the manufacture of the serving 2 then happen when the wrapping parts 3 not yet in contact with each other. First, the defined amount of additional sealants 9 to the seam surface 5 to the limited section 8th of the one wrapping part 3 appropriate. Subsequently, the other wrapping part 3 in contact with the first enclosure part 3 brought, whereby then the already provided amount of additional sealants 9 also with the seam area 5 of the other cladding part 3 in plant.
2 B) shows the arrangement according to 2a) , after on the seam section 4 the electrochemical cell 1 Heat was applied. It is a heated sealing bar 14 shown having a contour which the desired contour of the seam surfaces 5 after the heat treatment corresponds. By applying the heat melts the additional sealant 9 at least partially so that it can change its shape. Considered by the shape of the seal bars 14 nestles the additional sealant 9 in the gap from the conductor narrow side 10 and seam surfaces 5 the two wrapping parts 3 at. Beside the shown sealing bar 14 is on the other side of the electrochemical cell 1 another not shown seal bar shown, which also the contour of the seam surface 5 is adapted to the other Unhüllungsteils. The seal bar 14 is only partially shown. The seal bar 14 However, it is designed such that it is in contact with the entire seam section 4 one of the wrapping parts 3 can get into contact. Furthermore, the wrapping parts 3 by the application of heat elastically deformable and nestle, especially under the action of the sealing bars 14 , to each other and to the additional sealant 9 and to the current conductor 7 at. Further, a polymer layer, which is on an inner side of the wrapping parts produced by means of composite film 3 is arranged molten and can be in material contact with the auxiliary sealant 9 , with the arrester broadside 11 of the current conductor 7 and with a corresponding layer on the seam surface of the other wrapping part 3 devices. It arises in the 2 B) shown arrangement in which the additional sealant 9 the gap between the conductor narrow side 10 and serving parts 3 completely absorbs and thus produces a tight seal. It can be seen that in the field of current collector feedthrough 6 the seam surfaces 5 have a continuous shape, without causing corners or cracks in the contour of the seam surfaces 5 occur. The serving 2 indicates this in the field of current collector feedthrough 6 Reliable stability and safety against unwanted leakage.
In the embodiment according to 2 is the seam area 5 always directly on the respective wrapping part 3 arranged. Alternatively, the seam surface 5 even in sections directly at the respective wrapping part 3 be arranged and sections of a separate pre-seal 12 be provided as below with respect to 3 is explained in more detail.
It is in 3 to realize that the wrapping parts 3 in the area of the current collector feedthrough 6 with the current collector 7 and the auxiliary sealant 9 not in direct contact. Rather, between the wrapping parts 3 and the current collector 7 and the auxiliary sealant 9 a separate presealing element in the form of a Vorsiegelfolie 12 arranged. The presealing film 12 sets the seam surfaces 5 each one of the covering parts 3 at least in the limited section 8th and in the area of the current collector feedthrough 6 ready. The seam surface 5 , which in the present case in sections on a Vorsiegelfolie 12 is arranged, is in direct contact with the current collector 7 and the auxiliary sealant 9 , The manufacturing process which leads to an arrangement as in 3b) can lead in the following 4 to 7 explained in more detail.
It is in 4 a continuous band 13 from presealing film 12 shown. At predetermined intervals become current conductors 7 on the continuous band 13 hung up. Subsequently, by means of a nozzle melted, sealable polymer as an additional sealant on the tape 13 applied. The polymer may be fibrous. The polymer may have a round or square cross-section when applied. In a next process step, which in 5 shown is a second band 13 from presealing film 12 to the other side of the current collector 7 applied. The two Ableiterbreitseiten 11 are now both with Vorsiegelfolie 12 at least partially covered. The presealing film 12 which is on top of the current conductor 7 is applied is congruent with the presealing film 12 which down at the current conductor 7 is created. In a further step, the tape 13 from presealing film 12 laterally from the current conductor 7 and also laterally of the additional sealant 9 cut off. In 6 the aforementioned condition is shown in perspective view.
In the next step of the process, the seal bar is moved according to 7 from the outside onto the presealing film 12 applied. From the outside in this case means that the sealing bar is moved from the side to the Vorsiegelfolie, the current conductor 7 turned away. The seal bar can largely with the respect 2 described sealing bar 14 to match. Since, however, the areas to be sealed in the area of the presealing film are smaller than the areas to be sealed on the enclosure according to FIG 2 , The sealing bar can now be made smaller. There is a compression of the presealing film 12 , wherein in the area of the current conductor 7 and the additional sealant 9 the presealing film 12 each in contact with the current collector 7 or the additional sealant 9 device. Outside this range, the two Vorsiegelfolien advised 12 directly in contact with each other.
In a next process step, a so-illustrated composite 15 from presealing film 12 , Additional sealant 9 and current conductors 7 in the area of the current collector bushing 6 between the two enclosure parts 3 be applied and with a further seal with the wrapping parts 3 firmly connected. The method used for this purpose largely corresponds to the method which, with regard to 2 was described with the proviso that in place of the current conductor 7 according to 2 now the composite 15 in appendix to the abdomen parts 3 is brought. In this process step is a seam surface 5 * immediately at the wrapping parts 3 arranged. To a limited section 8th* the seam surface 5 * one of the wrapping parts 3 becomes a second defined amount of additional sealant 9 * appropriate. The limited section is an uneven area and corresponding adjacent areas of the seam area 5 * , During application of heat, the additional sealant may 9 * between seam surfaces 5 * and the composite 15 melt and cohesively with the composite 15 and the serving parts 3 devices. Here too, the advantages which have already been described with regard to the use of additional sealant arise.
enveloping part
Stromableiterdurchführung
Ableiterschmalseite
Ableiterbreitseite
Vorsiegelfolie
- DE 60004118 T2 [0002]
Method for producing an electrochemical cell ( 1 ), wherein the electrochemical cell ( 1 ) has at least one electrode stack, which within an enclosure ( 2 ), wherein the envelope ( 2 ) of at least two parts of the envelope ( 3 ), wherein the envelope parts ( 3 ) each have at least one seam surface ( 5 ), on which the envelope parts ( 3 ) are at least partially engageable with each other, comprising the following method steps: - attaching a defined amount of additional sealant ( 9 ) at least indirectly to a limited section ( 8th ) of the seam surface ( 5 ) at least one of the covering parts ( 3 ); - application of the seam surface ( 5 ) one of the wrapping parts ( 3 ) to the seam surface ( 5 ) of another of the envelope parts ( 3 ); - Subsequently applying heat to the seam surfaces ( 5 ).
Method according to the preceding claim, characterized in that the additional sealant ( 9 ) changes its shape during the application of heat.
Method according to at least one of the preceding claims, characterized in that the seam surfaces ( 5 ) directly on one of the wrapping parts ( 3 ) are arranged.
Method according to at least one of the preceding claims, characterized in that the seam surface ( 5 ) at least at the limited section ( 8th ) at least partially at one to the wrapping part ( 3 ) separate presealing element ( 12 ), in particular a presealing film, and the separate presealing element ( 12 ) in a further process step with at least one of the covering parts ( 3 ) is connected.
Method according to at least one of the preceding claims, characterized in that the seam surfaces ( 5 ) at least two enveloping parts ( 3 ) together on a separate presealing element ( 12 ) are arranged in the limited section, wherein a current conductor ( 7 ) together with the additional sealant ( 9 ) with the pre-seal element ( 12 ), in particular is enclosed annularly, and then the current conductor ( 7 ) together with the additional sealant ( 9 ) and the presealing element ( 12 ) in contact with at least one of the envelope parts ( 3 ) is brought.
Method according to at least one of the preceding claims, characterized in that the seam surfaces ( 5 ) and the additional sealant ( 9 ) are made of a similar material, in particular of an identical material.
Method according to at least one of the preceding claims, characterized in that the seam surface ( 5 ) at the limited section ( 8th ) has an uneven contour.
Method according to at least one of the preceding claims, characterized in that the additional sealant ( 9 ) in at least indirect plant to a current conductor ( 7 ), in particular to an arrester narrow side ( 10 ) of a current conductor ( 7 ) is brought.
Method according to at least one of the preceding claims, characterized in that a composite ( 15 ) from at least one current conductor ( 7 ), at least a defined amount of additional sealant ( 9 ) and at least one pre-seal element ( 12 ) in contact with at least one of the envelope parts ( 3 ) is brought, wherein at a limited portion between the enclosure part ( 3 ) and compound ( 15 ) a second defined amount of additional sealant ( 9 * ) is attached.
DE200910032523 2009-07-10 2009-07-10 Method for producing an electrochemical cell Withdrawn DE102009032523A1 (en)
DE200910032523 DE102009032523A1 (en) 2009-07-10 2009-07-10 Method for producing an electrochemical cell
US13/382,403 US20120159773A1 (en) 2009-07-10 2010-06-24 Method for producing an electrochemical cell
JP2012518785A JP2012532430A (en) 2009-07-10 2010-06-24 Method for producing electrochemical cell
EP10729800A EP2452382A1 (en) 2009-07-10 2010-06-24 Method for producing an electrochemical cell
CN201080031166XA CN102484226A (en) 2009-07-10 2010-06-24 Method for producing an electrochemical cell
KR1020127003435A KR20120083279A (en) 2009-07-10 2010-06-24 Method for producing an electrochemical cell
PCT/EP2010/003878 WO2011003520A1 (en) 2009-07-10 2010-06-24 Method for producing an electrochemical cell
BR112012000603A BR112012000603A2 (en) 2009-07-10 2010-06-24 "method for producing an electrochemical cell"
DE102009032523A1 true DE102009032523A1 (en) 2011-01-20
ID=42751489
DE200910032523 Withdrawn DE102009032523A1 (en) 2009-07-10 2009-07-10 Method for producing an electrochemical cell
US (1) US20120159773A1 (en)
EP (1) EP2452382A1 (en)
JP (1) JP2012532430A (en)
KR (1) KR20120083279A (en)
CN (1) CN102484226A (en)
BR (1) BR112012000603A2 (en)
DE (1) DE102009032523A1 (en)
WO (1) WO2011003520A1 (en)
RU189901U1 (en) * 2019-03-28 2019-06-10 Общество с ограниченной ответственностью Лысьвенский завод тяжёлого электрического машиностроения «Привод» (ООО «Электротяжмаш-Привод») Brushless-detector synchronous machine
DE60004118T2 (en) 1999-03-22 2004-07-15 Thomas & Betts International Inc., Sparks Method of treating contact connections on electrochemical cells, to achieve improved tightness, and hermetically sealed electrochemical cells which are produced therewith
JP4774594B2 (en) * 1998-10-30 2011-09-14 ソニー株式会社 Non-aqueous electrolyte battery and manufacturing method thereof
JP2002190283A (en) * 2000-12-21 2002-07-05 At Battery:Kk Manufacturing method of thin secondary battery and thin secondary battery
JP3758629B2 (en) * 2002-09-26 2006-03-22 日産自動車株式会社 Laminate sheet and laminate battery using the same
2009-07-10 DE DE200910032523 patent/DE102009032523A1/en not_active Withdrawn
2010-06-24 JP JP2012518785A patent/JP2012532430A/en active Pending
2010-06-24 BR BR112012000603A patent/BR112012000603A2/en not_active IP Right Cessation
2010-06-24 EP EP10729800A patent/EP2452382A1/en not_active Withdrawn
2010-06-24 CN CN201080031166XA patent/CN102484226A/en not_active Application Discontinuation
2010-06-24 KR KR1020127003435A patent/KR20120083279A/en not_active Application Discontinuation
2010-06-24 US US13/382,403 patent/US20120159773A1/en not_active Abandoned
2010-06-24 WO PCT/EP2010/003878 patent/WO2011003520A1/en active Application Filing
KR20120083279A (en) 2012-07-25
WO2011003520A8 (en) 2012-01-26
JP2012532430A (en) 2012-12-13
US20120159773A1 (en) 2012-06-28
EP2452382A1 (en) 2012-05-16
BR112012000603A2 (en) 2017-05-30
WO2011003520A1 (en) 2011-01-13
CN102484226A (en) 2012-05-30
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