EP3311432A1 - Method for producing an electrochemical bundle for a metal-ion battery comprising folding or coiling the sheet ends around themselves - Google Patents

Abstract

The invention relates to a method for producing an electrochemical bundle for a metal-ion battery, for electrical connection thereof to the output terminals of the battery, characterised by coiling or folding the sides of at least one of the two electrodes on itself, then compacting by packing in order to further increase the density of the coiled sides in order to weld the electrode to a current collector.

Description

 METHOD FOR PRODUCING A METAL-ION BATTERY ELECTROCHEMICAL BEAM WITH FOLDING OR WINDING

 EXTREMITES OF STRIP ON THEMSELVES

 Technical area

 The present invention relates to the field of electrochemical metal-ion generators, which operate according to the principle of insertion or deinsertion, or in other words intercalation-deintercalation, of metal ions in at least one electrode.

 It relates more particularly to a lithium electrochemical accumulator comprising at least one electrochemical cell constituted by an anode and a cathode on either side of a separator impregnated with electrolyte, two current collectors, one of which is connected to the electrolyte. anode and the other at the cathode, and a housing of elongate shape along a longitudinal axis (X), the housing being arranged to house the electrochemical cell with sealing while being traversed by a portion of the current collectors forming the terminals of output, also called poles.

 The separator may consist of one or more films.

 The housing may include a lid and a container, usually called a bucket, or have a lid, a bottom and a side shell assembled at both the bottom and the lid,

 The present invention aims to provide a part of the electrical connection between at least one electrochemical cell of the accumulator and its output terminals integrated into its housing.

 Although described with reference to a lithium-ion accumulator, the invention applies to any electrochemical metal-ion accumulator, that is to say also sodium-ion, magnesium-ion, aluminum-ion ...

 Prior art

As schematically illustrated in FIGS. 1 and 2, a lithium-ion battery or accumulator usually comprises at least one electrochemical cell C consisting of a separator impregnated with an electrolyte component 1 between a positive electrode or cathode 2 and a negative electrode or anode 3, a current collector 4 connected to the cathode 2, a current collector 5 connected to the anode 3 and finally a package 6 arranged to contain the electrochemical cell with sealing while being traversed by a portion of the current collectors 4 , 5, forming the output terminals. The architecture of conventional lithium-ion batteries is an architecture that can be described as monopolar, because with a single electrochemical cell comprising an anode, a cathode and an electrolyte. Several types of monopolar architecture geometry are known:

 a cylindrical geometry as disclosed in the patent application

US 2006/0121348,

 a prismatic geometry as disclosed in US Patents 734,8098 and 7338733;

 a stack geometry as disclosed in US patent applications 2008/060189, US 2008/0057392, and US patent 7335448.

 The electrolyte constituent may be of solid, liquid or gel form. In the latter form, the constituent may comprise a polymer or microporous composite separator impregnated with organic electrolyte (s) or ionic liquid type which allows the displacement of the lithium ion from the cathode to the anode to a charge and vice versa for a discharge, which generates the current. The electrolyte is generally a mixture of organic solvents, for example carbonates in which is added a lithium salt typically LiPF6.

The positive electrode or cathode consists of Lithium cation insertion materials which are generally composite, such as lithium iron phosphate LiFePO ₄ , lithium cobalt oxide LiCoO ₂ , lithiated manganese oxide, optionally substituted, LiMn ₂ 0 ₄ or a base material of LiNi _x Mn _y Co _z 0 ₂ with x + y + z = 1 such as LiNi. ₃₃ Mno. ₃₃ Coo. ₃₃ 0 _2, or a base material of LiNi _x Co _y Al _z 0 ₂ with x + y + z = 1, LiMn ₂ 0 _4, LiNiMnCo0 ₂ or nickel cobalt aluminum oxide lithiated LiNiCoA10 _2.

 The negative electrode or anode is very often made of carbon, graphite or Li 10 O 10 O (titanate material), possibly also based on silicon or lithium-based, or tin-based and their alloys or composite formed of silicon.

 The anode and the cathode of lithium insertion material can be deposited according to a usual technique in the form of an active layer on a metal sheet constituting a current collector.

The current collector connected to the positive electrode is usually aluminum. The current collector connected to the negative electrode is generally made of copper, nickel-plated copper or aluminum.

 Traditionally, a Li-ion battery or accumulator uses a couple of materials at the anode and the cathode to operate at a high voltage level, typically around 3.6 volts.

A Li-ion battery or accumulator comprises a rigid package or housing when the targeted applications are binding where a long life is sought, with for example much higher pressures to be withstood and a stricter required sealing level, typically less than 10 ^{~ 6} mbar.l / s helium, or in high stress environments such as aeronautics or space.

 The main advantage of rigid packages is their high sealing and maintained over time because the closure of the housings is performed by welding, generally by laser welding.

 The geometry of most rigid Li-ion battery packs is cylindrical because most of the battery electrochemical cells are coiled wound in a cylindrical geometry. Prismatic forms of boxes have also already been made.

 One of the types of cylindrical rigid case, usually manufactured for a high capacity Li-ion accumulator with a lifetime greater than 10 years, is illustrated in FIG.

 The housing 6 of longitudinal axis X comprises a cylindrical lateral envelope 7, a bottom 8 at one end, a cover 9 at the other end. The cover 9 supports the poles or output terminals of the current 40, 50. One of the output terminals (poles), for example the positive terminal 40 is soldered to the cover 9 while the other output terminal, for example the terminal negative 50, passes through the cover 9 with interposition of a not shown seal which electrically isolates the negative terminal 50 of the cover.

FIGS. 4 to 4B show the photographs of an electrochemical bundle F of shape elongate along a longitudinal axis XI and comprising a single electrochemical cell C such that it is usually wound by winding before the housing steps in a housing, electrical connection to the output terminals of the accumulator and its impregnation with an electrolyte. The cell C consists of an anode 3 and a cathode 4 on either side of a separator (not visible) adapted to be impregnated with the electrolyte. As can be seen, one of its lateral ends of the bundle F is delimited by strips 3 of the uncoated anode 3 while the other 11 of its lateral ends is delimited by strips 20 of the cathode 2 uncoated.

 By "uncoated strips" is meant here and in the context of the invention, the end portions of the metal sheets, also called strips, forming the current collectors, which are not covered with an insertion material lithium.

 The objective of the battery manufacturers is to increase the autonomy of a cell constituting the accumulator or their ability to operate at high power regimes while improving their lifetime, ie their number of possible cycles, their lightness and the manufacturing costs of these components.

 Improvement routes for Li-ion accumulators concern, for the most part, the nature of the materials and the methods of elaboration of the electrochemical cell components.

 Other possible ways of improvement, less numerous, concern accumulator boxes and methods and means for electrically connecting an electrochemical bundle to the two output terminals, also called terminals or poles of different polarity of the accumulator.

 To date, when it is desired to make an electrical connection between the electrochemical bundle and the output terminals of a Li-ion accumulator of cylindrical or prismatic geometry, which is of quality, it is intended to best respect the following design rules. :

 to satisfy the needs of an application in electrical conduction between each polarity of electrodes and the output terminals integrated in the battery case, for example in order to respond to power peaks while limiting the internal heating of the battery; accumulator capable of accelerating its electrochemical aging;

 - minimize the overall internal resistance level of the battery by making the electrical connection directly to the current collectors of the electrodes for each polarity and connecting an intermediate connecting piece between the electrochemical bundle and the battery housing;

- Simplify the connection to the electrochemical beam, making the connection directly to the uncoated electrode side strips, also called banks, delimiting respectively the two opposite side ends of the beam; optimizing the characteristics (thickness, height, mass) and profiles of the sidebands not coated with electrodes to achieve said electrical connection, in order to best satisfy the final assembly steps, that is to say the steps of integration of the electrochemical bundle in the housing, closure of the battery housing, electrolyte filling ....

 to minimize the mass and the volume necessary for producing the electrical connection which, as such, is not a generator of electrochemical energy, but which is necessary for the transfer of energy by the electrochemical bundle to the outside of the housing; 'accumulator.

 In the literature describing electrochemical beam production solutions of a cylindrical or prismatic accumulator and its electrical connection to the output terminals integrated into its housing, mention may be made of the following documents.

 The patent application WO2015 / 030541 discloses the welding of tabs ("tabs" in English) to the uncoated strips of the electrochemical bundle.

 The patent FR 2094491 discloses an alkaline accumulator whose electrical connection between the wound electrochemical cell and output terminals is obtained by cutting the banks of the electrodes by regularly spaced slots and then radial folding of the edges thus split from the outside of the inside under. the form of scales superimposed so as to form a substantially plane base on which is finally welded a current collector, constituted if necessary by the housing cover.

The patent application EP 1102337 discloses a Li-ion accumulator whose electrical connection between the electrochemical cell wound and output terminals is obtained by a single pressing of each end of the electrode strips of the wound cell, along the axis of winding, by means of a pressing mandrel and then, by laser welding of each end of the electrode strips with a terminal current collector consisting of a foil in the form of a disk and a connecting tongue itself. even laser welded subsequently to the housing cover, at one end and at the bottom of the housing, at the other end. Ribs are each made on a diameter of the disc and are themselves pressed beforehand the welding against the ends of pressed electrode strips. The patent application EP 1596449 describes a Li-ion accumulator whose electrical connection between the wound electrochemical cell and output terminals is obtained firstly by multiple pressing of each lateral end delimited by the uncoated strips of electrodes of the cell. wound, by means of a pressing mandrel of outside diameter between 15 and 20 mm. The pressing mandrel moves in a very short stroke alternately from the outside to the inside of the cell parallel to the winding axis by sweeping the entire side surface of the uncoated electrode strips to entangle between them. latter forming a flat and dense base on which is welded by laser or transparency a terminal current collector constituted by a foil in the form of a plane connection strip itself welded by laser or transparency thereafter to a output terminal integrated in the cover at one lateral end and at the bottom of the housing at the other end.

 By analyzing all the known solutions for electrochemical bundling of a lithium battery and its electrical connection to the output terminals of the accumulator, as described above, the inventors came to the conclusion that they were still be perfectible in many ways.

 First of all, the mass and the volume of the sidebands not coated with electrodes (banks) necessary for the electrical connection with the current collectors according to the state of the art are not necessarily optimized, which implies in the end a mass and a volume of the accumulator also not yet optimized.

 Then, the inventors found that de facto the banks of the same lateral end were not necessarily electrically connected to each other, in particular the parts of these banks located in the most peripheral zone of the beam. This implies a specific specific capacity of the electrochemical beam decreased, which can be detrimental especially for high power applications for the accumulator.

 Finally, the electrolyte filling step in an electrochemical battery of lithium accumulator, can be relatively long and delicate because the current collectors of the state of the art as welded on the banks of electrochemical accumulator beam constitute a significant obstacle to the passage of the electrolyte.

To overcome these drawbacks, the applicant has proposed in the application for Patent FR 3011128 A1 discloses a new method for producing an electrochemical bundle comprising a combination of two folding steps b / and a electrochemical bundle of separate accumulators in their implementation which make it possible to obtain two distinct zones on at least one , preferably each, of the lateral ends of the beam.

 This process is particularly efficient in terms of electrical conductivity and heat dissipation by the beam. However, its implementation can be restrictive in some applications.

 Thus, it is possible to classify the existing techniques and their drawbacks into two categories, to produce the accumulator electrochemical bundles and their electrical connection at their output terminals;

 - Beam winding formation and laying / welding tabs directly on the wound coil. This technique is relatively easy to implement, but inefficient in terms of electrical conductivity and heat removal by the beam;

 - formation by winding of the beam then operations of packing / compaction of the wound bundle. This technique of densifying the uncoated sidebands (banks) is efficient in terms of electrical conductivity and heat removal by the beam, but more complicated to implement.

 There is therefore a need to improve the electrochemical beam production of a lithium battery, more generally a metal-ion battery, and its electrical connection to the output terminals of the battery, in particular with a view to simplifying its implementation. maintaining good performance in terms of electrical conductivity and heat dissipation through the beam.

 The object of the invention is to respond at least in part to this need.

Presentation of the invention

 To this end, the invention relates, in one of its aspects, to a method for producing an electrochemical bundle (F) of a metal-ion accumulator (A), such as a Li-ion accumulator, in view of its electrical connection to the output terminals of the accumulator, comprising the following steps:

a / folding or winding on themselves the uncoated strip (s) of the anode and / or the cathode of at least one electrochemical cell constituted by the cathode and the anode on either side of a separator adapted to be impregnated with an electrolyte, so as to form a zone of extra thickness at the end of the strips;

 b / winding on itself by winding the electrochemical cell to form an electrochemical bundle having an elongate shape along a longitudinal axis X, with at one of its lateral ends, uncoated strips of the anode and the other of its lateral ends uncoated cathode strips;

 c / X-axis axial compression of the bands of the electrochemical bundle, on at least one surface comprising the zones of extra thickness at the end of the strips so as to obtain on the compressed surface portion, a substantially plane base intended to be welded to a current collector.

 Thus, the method according to the invention is characterized by the winding or folding on itself of the banks of at least one of the two electrodes and compacting by compaction to further densify the wound banks for the purpose of welding with a current collector.

 Thus, it is easy to obtain first local compaction (zones of extra thickness) at the end of the electrode and then compaction of all the zones of excess thickness in a mattress consisting of metallic material on a substantial part or even the entire surface at the end of the beam. , which makes it possible to carry out a quality welding of the positive and negative collectors on the zones thus prepared.

 In other words, by combining a local compaction and then all the already locally compacted areas (thicknesses), we obtain some sort of stratified strands of metal strip multilayer.

 The metal mat obtained in this way is homogeneous over all the end surface (s) of the electrochemical bundle.

 Axial compression is a simple compaction in one or a few passes, which can be fast.

 The method according to the invention can be implemented for electrodes whose metal strip is relatively thin or relatively thick in the case of application of power or target energy for the accumulator.

In addition, according to the invention, with a high densification of the folded and then compressed strip portions, the actual specific capacitance of the electrochemical bundle of an accumulator can be significantly increased. The method according to the invention is therefore a very good compromise between the existing techniques of electrical connection by tabs which have the advantage of being simple to implement and the techniques of axial electrochemical bundle tamping which make it possible to obtain good performance in terms of electrical conductivity and heat dissipation of the beam.

 The method is advantageously used for producing accumulators or Li-ion batteries.

 According to a first variant, step a / is carried out before step b /. Preferably, step a / is then performed during the cutting step, called "slitting step" of the electrodes.

 According to a second variant, step a / is carried out simultaneously in step b /. It is specified here, that "simultaneously" means in the context of the invention, the fact that we do not add an additional process step to manage, as the setting in another machine, but that the modifying only existing equipment for producing a metal-ion accumulator by adding a station for folding or winding on itself the electrode end. In addition, at the time, this step is performed in the unwound regions of the electrodes, and therefore does not add additional time to the process, since it is the same duration, for example corresponding to an electrode slit and roll it on itself at the same time, or not.

 Realizing the winding or folding of edges during the reposition of the electrodes or during the winding of the beam is advantageous because it does not induce any additional time in the realization of the beam compared to the known technique. In other words, this time is a masked production time. In other words, this makes it possible not to have to manage additional process steps, such as setting up another machine.

More particularly for the first or the second variant, it is possible to use a set of rollers and successive guides that allow to wind on itself the uncoated strip (bank) of the electrode. The technique used may for example be that already used in the paper industry such as book printing or the placing of sheets folded in envelopes for example. Thus, one can have the continuous sequence of the following steps, in an electrode winding equipment with their separator or in an equipment for slitting electrodes:

 - setting up an electrode coil in the equipment;

 - unwinding of the electrode in the equipment;

 in the zones where the electrode is unwound, rolling of the end by means of the guides and rollers;

 winding the electrode on an axis in the event of re-occurring, or otherwise winding the electrode with the reverse polarity electrode and their separator on an axis in order to constitute an electro-chemical beam;

 - Implementation of the other conventional steps of realization of the method of manufacturing a metal-ion battery.

 Advantageously, the axial compression according to step c1 is performed on the entire surface of a lateral end of the beam.

 The axial compression according to step c1 can be performed in one or more times.

 Advantageously, the axial compression comprises a step of axial tamping. This axial swaging may be optional or may be the axial compression step in its entirety. Thus, the tamping can be more or less pronounced, typically on a height between 0.2 to 2mm.

 According to an advantageous embodiment, the method comprises an additional step al /, between step a1 and step b /, of overwriting the zones of oversize. The crushing may be at the minimum thickness of the metal strip, or at a thickness to be agreed. Thus, the zones of extra thickness are further densified.

 The invention further relates to a method of producing an electrical connection portion between an electrochemical bundle of a metal-ion accumulator and one of the output terminals of the accumulator, comprising the following steps:

 - Realization of an electrochemical beam according to the method described above;

welding the zones of excess thickness, preferably of each base obtained, to a current collector itself intended to be electrically connected or connected to an output terminal of the accumulator. Advantageously, the step of welding a base to a current collector is performed by laser welding.

 The invention finally relates to a battery or metal storage battery comprising a housing comprising:

 a bottom to which is welded one of the current collectors welded to the electrochemical bundle according to the method described above; and

 a cover with a bushing forming an output terminal to which is welded the other of the current collectors welded to the electrochemical bundle according to the method described above.

 Preferably, for a Li-ion accumulator:

 the negative electrode material (s) is chosen from the group comprising graphite, lithium, titanate oxide Li4Ti05012; or based on silicon or lithium-based, or tin-based and their alloys;

the electrode material (s) positive (s) is selected from the group comprising lithium iron phosphate LiFePO ₄ , lithium cobalt oxide LiCo0 ₂ , lithiated manganese oxide, optionally substituted, LiMn ₂ 0 ₄ or a material based on LiNixMnyCoz0 ₂ with x + y + z = 1, such as LiNi0.33Mno.33Coo.33O2, or a material based on LiNixCoyAlzO ₂ with x + y + z = 1, LiMn ₂ 0 ₄ , LiNiMnCoO ₂ or lithiated nickel cobalt aluminum oxide LiNiCoA10 ₂ .

 detailed description

 Other advantages and characteristics of the invention will emerge more clearly from a reading of the detailed description of exemplary embodiments of the invention, given for illustrative and nonlimiting purposes, with reference to the following figures among which:

 FIG. 1 is a schematic exploded perspective view showing the various elements of a lithium-ion accumulator,

 FIG. 2 is a front view showing a lithium-ion battery with its flexible packaging according to the state of the art,

 - Figure 3 is a perspective view of a lithium-ion battery according to the state of the art with its rigid packaging consisting of a housing;

- Figure 4 is a perspective view of an electrochemical bundle of a lithium-ion battery according to the state of the art, the beam consisting of a single electrochemical cell wound on itself by winding; FIG. 4A is a photographic view from above of a lateral end of the electrochemical bundle according to FIG. 4;

 FIG. 4B is a photographic view from above of the other lateral end of the electrochemical bundle according to FIG. 4;

 FIGS. 5 to 5D are diagrammatic views showing the successive steps of an example according to the invention of a process for producing an electrochemical bundle and a part of its electrical connection to the output terminals of the accumulator which 'integrated; Figure 5Ά being a variant of Figure 5A;

 FIG. 6A is a schematic view of a first variant of a step of the method according to the invention described with reference to FIGS. 5 to 5D;

 - Figure 6 'A is a schematic view of a second variant of a step of the method according to the invention described with reference to Figures 5 to 5D.

 It is specified that the same elements in a battery according to the state of the art and in an accumulator according to the invention are designated by the same referenced for purposes of clarity.

 It is specified that the various elements according to the invention are represented solely for the sake of clarity and that they are not to scale.

 Figures 1 to 4B have already been discussed in detail in the preamble. They are therefore not described below.

 To improve the electrical connection between an electrochemical bundle of a Li-ion accumulator and its output terminals, the inventors propose a new method for producing the electrochemical bundle.

 The metal strips supporting the electrode materials may have a thickness of between 5 and 50 μιη. For anode foil 3, it may advantageously be a copper foil thickness of the order of 12 μιη. For a cathode strip 2, it may advantageously be an aluminum strip thickness of the order of 20 μιη.

 The various steps of this embodiment of the invention will now be described with reference to FIGS. 5 to 5D.

It is specified that the process is completely described from anode 3. The method also applies in the same way to a cathode 2. It is also possible to make an electrochemical bundle F and its electrical connection part. only to the anode 3 according to the method according to the invention, the embodiment and the connecting portion to the cathode 2 can be made according to an existing method, and vice versa.

 It starts from an anode 3 whose metal strip supports in its portion 31 of lithium insertion material 32, while its lateral end strip (bank) 30 is bare, that is to say devoid of materials lithium insertion (FIG. 5).

 Step a /: The end of the edge 30 is wound on itself in order to obtain a thickened area 30R (FIG. 5A).

 As a variant, instead of winding it on itself, the end of the edge 30 can always be folded back on itself in order to obtain a thickening zone 30p (FIG. 5 Ά).

 Step b /: The anode 3, the cathode 2 and at least one separator film of the electrochemical cell C around a support not shown are then wind-wound.

 The beam thus has a cylindrical shape elongate along a longitudinal axis X, with at one of its lateral ends, strips 30 of the anode 3 uncoated and at the other 1 1 of its lateral ends of the strips 20 of uncoated cathode. The initial beam according to the invention is therefore like that shown in FIGS. 4 to 4B, with, in addition, at the end of the banks 20, 30 zones of excess thickness 20R, 30R (FIG. 5B).

 Step c /: Then performs an axial tamping along the X axis of the strips 20, 30 of the electrochemical bundle, over the entire surface of the lateral ends 10, 1 1, and therefore on all the excess areas 20R, 3 OR.

 Axial tamping consists of compression by a flat or structured tool bearing surface substantially equal to the surface of each of the lateral ends of the strips 20 or 30.

 When the desired geometry of the accumulator is cylindrical, the tool and the electrochemical bundle are arranged coaxially during axial swaging.

Axial tamping is performed once or several times. It can consist of a compression according to one or more relative movements back and forth, ie at least one round-trip along the X axis of the beam, and until reaching a desired dimension of the beam along X, or an effort maximum compression whose value is predetermined beforehand. This produces on the packed surface 20 _RT , _RT a substantially _flat base, intended to be welded to a current collector (Figure 5C).

Thus, at this stage, a local compaction of the strips 20, 30 (shims) has been achieved by the creation of the excess areas 20 _R , 3 O _R and a global compaction on all the end surfaces of the bundle F. , by the axial swaging of the areas of extra thickness. The banks 20, 30 have thus been doubly densified into a consistent mat allowing a good laser welding of the positive and negative collectors to the zones thus prepared.

Step d /: the laser welding L is then carried out at one of the lateral ends 1 1 of the bundle, the base formed by the packed excess thickness zones 20 _RT of the cathode (positive banks) with a conventional current collector 24 under the form of a solid disc (Figure 5D), itself intended to be welded thereafter with the bottom 8 of the battery housing 6.

The same is done in the same manner at the other of the lateral ends 10 of the bundle, with the base formed by the packed excess thickness zones _RT of the anode (negative banks) with a current collector portion 34 in the form of a solid disk pierced at its center and a tongue (not shown) projecting laterally from the disk (FIG. 5D), the tongue itself being intended to be welded to the negative output terminal 50 mounted therethrough in the cover 9 of the casing accumulator.

 Other variants and improvements can be made without departing from the scope of the invention.

Thus, for example, once the winding or folding on itself of the anode 3 or the cathode 2, it is possible before step b / winding the beam, to crush the zones of allowance 20 _R , 30 _R to further densify these areas (Figure 6A). We can also get rid of this crash (Figure 6Ά).

 The invention is not limited to the examples which have just been described; it is possible in particular to combine with one another characteristics of the illustrated examples within non-illustrated variants.

Claims

 1. A method for producing an electrochemical bundle (F) of a lithium accumulator (A), such as a Li-ion accumulator, for its electrical connection to the output terminals of the accumulator, comprising the steps following:

 a / folding or winding on themselves the uncoated strip (s) (20, 30) of the anode and / or the cathode of at least one electrochemical cell (C) consisting of the cathode (2) and the anode (3) on either side of a separator (4) adapted to be impregnated with an electrolyte, so as to form a zone of extra thickness (20R, 20P; 3 OR , 30P) at the end of the strips;

 b / winding on itself by winding the electrochemical cell to form an electrochemical bundle (F) having an elongated shape along a longitudinal axis X, with at one (10) of its lateral ends, strips (30) ) of the uncoated anode and the other (1 1) of its lateral ends uncoated strips (20) of the cathode;

c / axial compression along the X axis of the electrochemical bundle strips (20, 30), on at least one surface comprising the zones of excess thickness (20R, 20P, 3 OR, 30P) at the ends of the strips so as to obtain on the compressed surface portion, a substantially planar base (20RT, 30RT ₎ for being welded to a current collector.

 2. Method of producing an electrochemical bundle according to the claim

1, step a / being performed before step b /.

 3. A method of producing an electrochemical bundle according to claim 1 or 2, the step a / being performed during the cutting step, called "slitting step" of the electrodes.

 4. Process for producing an electrochemical bundle according to the claim

1, step a / being performed simultaneously in step b /.

 5. A method of producing an electrochemical bundle according to one of the preceding claims, the axial compression according to step cc being performed over the entire surface of a lateral end of the beam.

6. A method of producing an electrochemical bundle according to one of the preceding claims, the axial compression according to step cl being performed in one or more times.

7. A method of producing an electrochemical bundle according to one of the preceding claims, the axial compression comprising an axial compacting step.

 8. A method of producing an electrochemical bundle according to one of the preceding claims to the exclusion of claim 4, comprising a further step al /, between step a / and step b /, consisting in crushing the zones of overthickness formed (20R, 20P, 3 OR, 30P).

 9. A method of producing an electrical connection portion between an electrochemical bundle (F) of a metal-ion accumulator (A) and one of the output terminals of the accumulator, comprising the following steps:

 - Realization of an electrochemical bundle (F) according to the method according to one of claims 1 to 8;

 welding the zones of excess thickness (20R, 20P, 30R, 30P), preferably of each base (20RT, 30RT) obtained, to a current collector (24, 34) itself intended to be electrically connected or connected to a output terminal of the accumulator.

 10. A method of producing an electrical connection portion according to claim 9, the step of welding a base to a current collector being made by laser welding.

 1. A battery or metal storage battery comprising a housing comprising:

 a bottom to which is welded one of the current collectors welded to the electrochemical bundle according to the method according to one of claims 9 or 10; and

 - A cover with a bushing forming an output terminal to which is welded the other current collectors welded to the electrochemical bundle according to the method according to one of claims 9 or 10.

 12. Li-ion battery or accumulator according to claim 11, wherein:

the negative electrode material (s) is chosen from the group comprising graphite, lithium and titanate oxide; _; or based on silicon or lithium-based, or tin-based and their alloys;

the electrode material (s) positive (s) is selected from the group comprising lithium iron phosphate LiFePO ₄ , lithium cobalt oxide LiCo0 ₂ , lithiated manganese oxide, optionally substituted, LiMn ₂ 0 ₄ or a material based on LiNi _x Mn _y Co _z 0 ₂ with x + y + z = 1, as LiNio.33Mno.33Coo.33O2, or a base material of LiNi _x Co _y Al _z 02 with x + y + z = 1, LiM ^ C ^, LiNiMnCo0 ₂ or nickel oxide cobalt aluminum lithium LiNiCoA10 ₂ .