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    • 专利摘要:
    The invention relates to a terminal crossing, made through an orifice opening out on either side of a wall of the case of an accumulator, comprising: - an electrically conductive male part (5), internally comprising a passage opening towards the outside of the accumulator and intended to circulate a cooling fluid having circulated along the longitudinal axis of the accumulator; - an electrically conductive female part (50), fitted tightly around a part of the male part, outside the accumulator; - two electrically insulating washers (48, 49), each comprising a support portion in surface support with pressure both against one of the faces of the wall and a guide portion projecting relative to the support portion and in contact with the edge of the orifice; the bearing portions of the washers being pressed against the female part and against a part of the male part.
    公开号:FR3075477A1
    申请号:FR1762152
    申请日:2017-12-14
    公开日:2019-06-21
    发明作者:Pierre Jost;Frederic Dewulf;Johann Lejosne
    申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    TERMINAL FORMING TERMINAL FOR ACCUMULATOR
    METAL-ION ELECTROCHEMICAL, ASSOCIATED ACCUMULATOR
    Technical area
    The present invention relates to the field of metal-ion accumulators.
    More particularly, the invention relates to a module of metalion accumulators aligned in a tube and in electrical series.
    The invention aims first of all to improve the electrical and thermal uniformity of accumulators within a battery pack.
    For this, the invention provides modular electrical and thermal management of the pack from the same unitary accumulator.
    Lastly, it offers increased security for the pack via electrical control, thermal control and gas detection.
    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 illustrated diagrammatically in FIGS. 1 and 2, a lithium-ion battery or accumulator usually comprises at least one electrochemical cell C consisting of 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 part of the current collectors 4, 5 .
    Several types of accumulator architecture geometry are known:
    - a cylindrical geometry as disclosed in the patent application US 2006/0121348,
    - a prismatic geometry as disclosed in US patents 7348098, US 7338733;
    - a stacked geometry as disclosed in patent applications US 2008/060189, US 2008/0057392, and US patent 7335448.
    The electrolyte component 1 can be solid, liquid or gel. In the latter form, the constituent may comprise a separator made of polymer, ceramic or microporous composite soaked with organic electrolyte (s) or of ionic liquid type which allows the displacement of the lithium ion from the cathode to the anode for a charge and vice versa for a discharge, which generates the current. The electrolyte is generally a mixture of organic solvents, for example carbonates to which is added a lithium salt typically LIPP6.
    The positive electrode or cathode 2 is made of lithium cation insertion materials which are generally composite, such as LiFePO 4 , LiCoCL, LiNio.33Mno.33Coo.33O2.
    The negative electrode or anode 3 is very often made of graphite carbon or of Li 4 TiO 5 Oi2 (titanate material), possibly also based on silicon or of composite formed on silicon basis.
    The current collector 4 connected to the positive electrode is generally made of aluminum.
    The current collector 5 connected to the negative electrode is generally made of copper, nickel-plated copper or aluminum.
    A lithium-ion battery or accumulator can obviously comprise a plurality of electrochemical cells which are stacked on top of each other.
    Traditionally, a Li-ion battery or accumulator uses a couple of materials at the anode and at the cathode allowing it to operate at a high voltage level, typically equal to 3.6 Volt.
    Depending on the type of application targeted, it is sought to produce either a thin and flexible lithium-ion accumulator or a rigid accumulator: the packaging is then either flexible or rigid and in the latter case constitutes a sort of case.
    Flexible packaging is usually made from a multilayer composite material, consisting of a stack of aluminum layers covered by one or more polymer film (s) laminated by gluing.
    Rigid packaging is used when the intended applications are restrictive or where a long service life is sought, for example with pressures to be supported much higher and a required level of tightness more strict, typically less than 10 ' 8 mbar.l / s, or in environments with high constraints such as aeronautics or space.
    Also, to date a rigid packaging used consists of a metal case, generally made of metal, typically of stainless steel (stainless steel 316L or stainless steel 304) or aluminum (Al 1050 or Al 3003), or even of titanium. In addition, aluminum is generally preferred for its high coefficient of thermal conductivity as explained below.
    The geometry of most rigid cases of Li-ion battery packagings is cylindrical, since most of the electrochemical cells of accumulators are wound by winding in a cylindrical geometry around a cylindrical mandrel. Prismatic forms of housings have also already been produced by winding around a prismatic mandrel.
    Patent application FR3004292 describes the use of the interior of the mandrel as an air knife to cool the core of a cell wound with a metal-ion accumulator.
    One of the types of rigid cylindrical case, usually manufactured for a high capacity Li-ion accumulator, is illustrated in FIG. 3.
    A rigid prismatic case is also shown in Figure 4.
    The housing 6 comprises a cylindrical lateral casing 7, a bottom 8 at one end, a cover 9 at the other end, the bottom 8 and the cover 9 being assembled to the casing 7. The cover 9 supports the poles or terminals of current output 4, 5. One of the output terminals (poles), for example the positive terminal 4 is soldered to the cover 9 while the other output terminal, for example the negative terminal 5, passes through the cover 9 with the interposition of a seal (not shown) which electrically isolates the negative terminal 5 from the cover.
    The type of rigid housing widely produced also consists of a stamped cup and a cover welded together on their periphery by laser. On the other hand, current collectors include a bushing with a part projecting from the top of the case and which forms a terminal also called the apparent pole of the battery.
    The difficulty in producing such a terminal lies mainly in the assembly of the various components of the battery in order to have a robust design. The nature of the materials used is also important in order to be compatible with certain electrochemical couples. Indeed, Li-ion technology preferably requires selecting a grade of aluminum as pure as possible inside the accumulator to avoid the presence of pollution and the generation of galvanic torque in the presence of the electrolyte that can lead to corrosion.
    In addition, a waterproof crossing terminal must be mechanically robust and meet the following conditions:
    - not to deform during the assembly steps of the accumulator;
    - withstand a tightening torque, generally greater than 3N.m, which should allow the assembly of the accumulator into a module;
    - remain intact throughout the lifetime of an accumulator in its application, that is to say withstand vibrations, mechanical shocks, variations in temperature and pressure, without deformation and without leakage;
    - allow high currents that can exceed 5 OA to be drained, in the case of a single accumulator, with a capacity of less than 5Ah nominal, so that it can be used in power applications.
    An example of an advantageous assembly of a terminal crossing with a current collector and with the cover of a housing is described in the international application filed by the Applicant on September 1, 2017 under the n ° PCT / EP2017 / 071951.
    A P battery pack consists of a variable number of accumulators up to several thousand which are electrically connected in series or in parallel with each other and generally by connection bars, usually called busbars.
    An example of a battery pack P is shown in FIG. 5. This pack consists of two modules Ml, M2 of identical Li-ion accumulators A and connected together in series, each module Ml, M2 consisting of four rows of accumulators connected in parallel, each row consisting of a number equal to six Li-ion accumulators.
    As shown, the mechanical and electrical connection between two Li-ion accumulators in the same row is made by screwing busbars Bl, advantageously made of copper, each connecting a positive terminal 4 to a negative terminal 5. The connection between two rows of accumulators in parallel within the same module Ml or M2 is provided by a busbar B2, also advantageously made of copper. The connection between the two modules Ml, M2 is provided by a busbar B3, also advantageously made of copper.
    In the development and manufacture of lithium-ion batteries, for each specific charge / discharge profile for each new request, regardless of the market players, this requires precise sizing (electrical architects series / parallel, mechanical, thermal, etc.). .) to optimally design an efficient and safe battery pack.
    A lithium electrochemical system, whether at the cell, module or pack scale, produces exothermic reactions whatever the given cycling profile. Thus, on the scale of a unitary accumulator, depending on the chemistry considered, the optimal functioning of lithium ion accumulators is limited within a certain temperature range.
    An accumulator must control its temperature, typically generally below 70 ° C on its outer surface of the housing, in order to avoid leaving in thermal runaway which can be followed by a generation of gas and explosion and / or fire.
    Also, maintaining a temperature below 70 ° C increases its lifespan, because the higher the operating temperature of an accumulator, the more its lifespan will be reduced.
    In addition, certain chemistries of accumulators require an operating temperature well above the ambient temperature and consequently, it proves necessary to regulate their temperature level by an initial preheating of the accumulators, even by a maintenance in permanent temperature. accumulators.
    In a battery, or battery pack with several Li-ion accumulators, the placing in series or parallel of more or less different accumulators can have consequences on the resulting performances and durability for the pack.
    It is thus recognized that in a battery pack, for example of an electric vehicle, the dispersions of aging can be high depending for example on the position of the accumulators, following asymmetries of aging between the accumulators or differences in uses ( thermal variations between the core and the edges of the pack, current gradient ...). Thus, differences in SOH health states of around 20% between accumulators in the same pack can be observed.
    Also, in order to limit the premature aging of the pack, it is necessary to optimize the operating temperature and the temperature dispersion from one accumulator to another. One accumulator (or accumulators) that ages (age) faster than the others can (can) have a direct impact on the electrical performance of the complete battery pack.
    At the module and pack scale, typically below 0 ° C for example, it may be necessary to have recourse to special control via a BMS, in order to limit the power required from the pack and to avoid degradation accumulators.
    It is recalled here that the BMS (English acronym for "Battery Management System") is used to monitor the state of the various accumulators (state of charge, state of health, etc.) and to control the various safety elements, such currents should not be too high, unsuitable potentials (too high or too low), limit temperatures and therefore has the function in particular of stopping current applications as soon as threshold voltage values are reached, ie a potential difference between the two active insertion materials. The BMS therefore stops current applications (charging, discharging) as soon as threshold voltages are reached.
    Above a higher temperature, typically of the order of 70 ° C, it is also advisable to be vigilant because electrochemical reactions can lead to the destruction of unitary accumulators and cause a propagation of an internal defect in the accumulator. , typically an internal short circuit, which can lead to the extreme explosion of the pack. In this case, it is also necessary to have recourse to BMS, in order to protect the accumulators.
    Consequently, a battery pack generally requires a very efficient BMS, in order to generate voltage balances.
    Conversely, we understand that a thermally balanced battery pack is also a necessity.
    The difficulty arises in ensuring uniformity of temperature within a battery pack.
    In the literature, the solutions disclosed in an attempt to ensure temperature uniformity within a battery pack can be classified essentially into three categories.
    The first category concerns solutions where a heat transfer fluid (gaseous or liquid) is circulated within a battery pack.
    Patent US5320190 thus proposes an air circulation to cool a vehicle battery pack, either by directly using the air impacting the vehicle during taxiing, or by using a fan for the parked phases or just after taxiing. .
    Patent CN202259596U offers a battery pack which incorporates air distributors.
    In patent application WO2012 / 165781, a system of air guide plates is proposed which a priori makes it possible to reduce the temperature difference between battery modules.
    Coolant can be used in place of air. However, the concepts of cost, size and additional mass can be major factors depending on the application considered.
    For example, air cooling is the cheapest solution since, as indicated, it consists of forced air ventilation between the accumulators. On the other hand, the thermal performance of air cooling is of poor quality due to the low exchange coefficient and its low thermal inertia. Thus, in this type of cooling, the first accumulator will heat up despite everything in contact with the air and the air temperature will increase. When the second accumulator passes, the air is warmer and the accumulator is warmer than the first. In the end, we thus obtain accumulators whose temperature is inhomogeneous.
    Liquid cooling solutions are much more effective.
    For example, patent applications WO2008 / 156737 and US2013 / 196184 propose a system of channels which each follow a part of the periphery of several cylindrical accumulators parallel to each other A heat transfer liquid flows inside these channels to drain the heat.
    Patent US8877366 relates to a liquid cooling solution flowing in external pipes which cool by thermal conduction of the fins inserted between accumulators.
    The second category concerns the use of cold plates.
    US Pat. No. 8,609,268 thus discloses a cold plate system inside which a coolant flows, making it possible to drain the heat from accumulators in contact with the cold plate.
    Patent application WO2011 / 013997 proposes cooling fins arranged inside a stack of flat cells to drain the heat from the cells towards a fluid circulating at the bottom of the stack.
    The third category concerns cooling by phase change material. Thus, patent application US2006 / 0073377 proposes to regulate the temperature of the cells which are embedded in the phase change material. The material is placed inside a rigid envelope that contains the electrochemical cells and fills the spaces between adjacent cells.
    All the solutions proposed so far are not completely satisfactory because the temperature level of the accumulators in operation remains high and the temperature uniformity between accumulators is insufficient.
    There is a need to improve the solutions for thermal management of metal-ion accumulators, in particular in order to reduce their operating temperature and to homogenize them when they are assembled by forming a battery pack and thus increase the duration of life of the latter and this, while defining a modular pack optimized in terms of power, size and weight.
    In addition, the improvement must not be at the expense of the need to control the operational safety of each accumulator, in particular due to a generation of gases and / or thermal runaway.
    The object of the invention is to meet these needs at least in part.
    Statement of the invention
    To do this, the invention relates, in one of its aspects, and according to a first alternative, to an accumulator module comprising:
    - a tube;
    - A plurality of metal-ion accumulators each comprising an electrochemical cell C formed of a cathode, an anode and an electrolyte interposed between the cathode and the anode, and a housing arranged to seal the electrochemical cell wound by winding around a mandrel; the accumulators being arranged coaxially along their longitudinal axis (X) inside the tube; the accumulators being connected in electrical series with one another;
    - a heat transfer fluid circuit configured to circulate a heat transfer fluid inside the accumulators at least along the length of the mandrels.
    According to a second alternative which can be independent or combined with the first alternative, the invention relates to a battery module comprising:
    - at least one tube;
    a plurality of metal-ion accumulators each comprising an electrochemical cell C formed by a cathode, an anode and an electrolyte interposed between the cathode and the anode, and a casing arranged to contain the electrochemical cell with sealing wound by winding around a mandrel; the accumulators being arranged coaxially along their longitudinal axis (X) inside the tube; the accumulators being connected in electrical series with one another;
    - a circuit or a reservoir of heat transfer fluid delimited at least by the tube and configured (e) to at least bring a volume of heat transfer fluid into contact over the entire periphery of the accumulator boxes.
    Thus, the invention consists in defining a completely independent module with a tube which serves as a housing for a plurality of accumulators aligned one after the other, the accumulators being electrically connected together in series and fluidly by a common circuit coolant which will flow continuously in the heart of the electrochemical bundles of all the accumulators and / or in an external envelope defined by the housing tube, in contact with the accumulator housings.
    Thanks to the invention, the thermal of a complete battery pack can be managed in a modular manner by connecting in series or in fluidic parallel therebetween several accumulator modules which are furthermore connected together in series or in electrical parallel.
    As a result, cooling or reheating a battery pack is simplified. For example, if the battery pack includes a number N of accumulators to maintain in temperature, the N accumulators can be divided into several modules M. If the N accumulators operate in the same way, it is advantageous to have the same flow rate within each of the M modules. If certain accumulators N operate differently and therefore heat more, it is also possible to regulate the flow rate of each of the M modules.
    According to a first variant, the reservoir can be a closed double-walled tank, the inner or outer wall of which is defined by the tube, the closed double-wall being filled with a phase change material (MCP).
    According to a second variant, the circuit can comprise a double-walled conduit, the internal or external wall of which is defined by the tube, the double-wall being emerging at one of its ends by a fluid supply orifice and at the 'other of its ends by a fluid outlet orifice, to circulate the heat transfer fluid over the entire periphery of the battery boxes, from the supply orifice to the outlet orifice.
    The module may include two sealed fluid connections each passing longitudinally through the interior of one end of the double wall.
    In place of the waterproof connections, the module can include:
    - two sealed closing elements each closing longitudinally one end of the double wall;
    - At least two sealed fluid collectors each laterally passing through one end of the double wall.
    Advantageously, each of the closure elements comprises an electrically conductive central part, forming the electrical output terminal of the module and a peripheral part, around its central, electrically insulating part.
    According to an alternative embodiment, the double-walled conduit can be constituted by two concentric tubes distinct from the accumulator housings, the inner tube being in direct contact with the lateral envelopes of the accumulator housings.
    According to another alternative embodiment, the inner wall of the double-walled duct is delimited by the lateral envelopes of the accumulator housings, the outer wall being constituted by the tube.
    Advantageously, the module comprises centering means either between the inner tube and the outer tube, or between the lateral envelopes of the housings and the outer tube.
    Advantageously also, the centering means can be constituted either by a plurality of fins or inserts distributed uniformly around the periphery of the inner tube or the lateral envelopes of the housings, or by a helically shaped fin wound around the inner tube or around lateral envelopes of the housings, either by a foam homogeneously filling the volume between the inner tube and the outer tube or between the lateral envelopes of the housings and the outer tube.
    Advantageously, means of electrical insulation are provided between the fins or foam and the inner tube.
    According to an advantageous embodiment:
    - Each accumulator comprises a crossing forming an output terminal projecting from the bottom or the cover of the case;
    - The tube houses mechanical compression means arranged at least at one of the ends of the tube, to ensure the longitudinal positioning inside the tube while guaranteeing electrical insulation with respect to the tube.
    Each accumulator can be a Li-ion accumulator in which:
    - the material of negative electrode (s) is chosen from the group comprising graphite, lithium, titanate oxide Li ^ iCLOn;
    - the material of positive electrode (s) is chosen from the group comprising LiFePCL, LiCoO2, LiNio.33Mno.33Coo.33O2.
    The invention also relates to a module (M) of accumulators according to the first alternative in combination with the second alternative.
    The invention also relates to a battery pack comprising a plurality of modules (M) of accumulators described above, electrically connected in series or in parallel, with the plurality of heat transfer circuits fluidly connected in series or in parallel.
    According to an advantageous embodiment, the battery pack comprises:
    - a plurality of modules (M) of accumulators according to the second alternative and if necessary according to the first alternative, each module (M) comprising a single tube inside which the aligned accumulators are housed;
    - two tubular holding plates each pierced with a plurality of orifices parallel to each other, the number of which is the same as that of the plurality of tubes of the accumulator modules (M), each of the two ends of each tube being engaged in an orifice for holding a tubular plate while being tightly fixed to the latter;
    - a hollow body forming a shell tightly fixed around the tubular plates to delimit the heat transfer circuit; the calender comprising at one of its ends a fluid inlet orifice and at the other of its ends a fluid outlet orifice.
    In another of its aspects, the invention relates to a gas tracking system within a battery pack, comprising:
    - a battery pack comprising metal-ion electrochemical accumulators,
    - a heat transfer fluid circuit for cooling or heating the accumulators, comprising an expansion tank adapted to collect and detect the gases released by each of the accumulators and having circulated in the heat transfer fluid.
    According to an advantageous embodiment, the system comprises a safety member to protect the expansion tank from overpressure caused by the gases of the accumulators.
    The safety device is preferably a valve, and / or a regulating device controllable by the battery pack accumulator control system (BMS).
    The invention also relates to a metal-ion electrochemical battery or accumulator, for a monitoring system as described above, comprising a rupture membrane permeable to gases and impermeable to the heat transfer fluid, the membrane being arranged and fixed in the accumulator for allow the gases released by the accumulator to pass outside of the latter.
    The accumulator can include a terminal crossing, made through an orifice opening on either side of a wall of the accumulator housing, comprising:
    - an electrically conductive part, internally comprising a passage intended to lead to the outside of the accumulator, and a through hole which joins the interior of the part;
    - the diaphragm with rupture forming a safety vent in the event of gas overpressure, the membrane being fixed, on the through hole.
    Advantageously, the membrane is in the form of a disc sandwiched on the through hole by means of a metal crown welded to the electrically conductive part.
    The electrically conductive part is preferably a male part projecting from the accumulator housing.
    The male part is preferably made of nickel-plated copper or aluminum alloy,
    According to an advantageous mode, the crossing comprises:
    - an electrically conductive female part, of annular shape, fitted tightly around a part of the male part, outside the accumulator;
    - two electrically insulating washers, each comprising a support portion in surface support with pressure both against one of the faces of the wall and a guide portion projecting from the support portion and in contact with the edge of the orifice; the bearing portion of a washer being pressed against the female part; the bearing portion of the other washer being pressed against a part of the male part.
    According to an advantageous alternative embodiment, the male part comprises:
    - a thread, intended to cooperate by screwing with another thread for fixing and electrical outlet of the accumulator;
    - a first enlargement diameter below the thread and which serves as a crimping diameter for the female part, and
    - a second enlargement in diameter in the continuity of the first which serves as both a support surface with the electrical insulation washer and a connection surface to a current collector intended to make the electrical connection with the electrochemical cell of the 'accumulator.
    The male part may include, in its lower part, below the second diameter enlargement, a reduction in diameter integrating the through hole on which the rupture membrane is fixed.
    The bushing can be made through the cover of the housing, which is advantageously made of aluminum, such as aluminum 1050 or 3003.
    According to an advantageous embodiment, the rupture membrane is arranged in the empty volume delimited between the cover and the current collector of the electrical connection between the terminal and the electrochemical cell of the accumulator.
    The invention relates in another of its aspects, to a mechanical interface and electrical insulation part, intended to produce the mechanical interface and the insulation between two metal-ion electrochemical accumulators aligned along their longitudinal axis (X), each of the two accumulators comprising a housing with a bottom and a cover through which a passage forming the output terminal of the accumulator, the part being made of electrically insulating material and constituted by a flange comprising:
    - A flat base, adapted to be applied against the cover of one of the two accumulators, the flat base being pierced with a through opening whose diameter is adapted to that of a part of the output terminal of the accumulator which is housed there;
    - An annular wall surrounding the flat base and shaped to delimit on the one hand an annular groove of complementary shape with that of the top of a case of one of the accumulators, including the shape of the cover, so that it can be fitted therein and secondly a bearing surface with the bottom of the housing of the other of the accumulators.
    The annular groove is advantageously dimensioned to produce a fitting with a tight fit on the top of the accumulator housing.
    According to an advantageous embodiment, the collar further comprises a plurality of spacer tabs distributed at the periphery of the annular wall, the tabs being adapted to guarantee a fixed spacing with an outer tube in which the aligned accumulators are housed coaxially. Preferably, the spacer tabs are distributed uniformly according to a spacing step e5.
    According to another advantageous embodiment, the collar is shaped so as to leave an empty volume between the flat base which is applied against the cover of the case of one of the two accumulators and the bottom of the case of the other of the accumulators.
    Advantageously, the part is produced by injection of a plastic material, in particular a PA6-6 or a polyoxymethylene (POM).
    The invention also relates to an accumulator module, comprising:
    - at least two metal-ion electrochemical accumulators aligned along their longitudinal axis (X);
    - a mechanical interface and electrical insulation part described above, arranged between the two accumulators.
    The two accumulators are also advantageously assembled together by means of the output terminal of one of the accumulators screwed onto the hollow mandrel of the other of the accumulators, through the bottom of the latter.
    Advantageously, an electronic module is provided which is supported by the flat base in the empty volume or integrated into the thickness of the flat base, the electronic module being adapted to monitor the electrical characteristics of one or other of the accumulators.
    According to an advantageous alternative embodiment, the electronic module is electrically supplied on the one hand by a wire of a polarity, through the flange to connect it electrically to the cover of the accumulator on which the flat base of the flange s' presses and other by another electric supply wire, of opposite polarity, to connect it electrically to a part of the output terminal of the accumulator.
    The invention also relates to a battery pack comprising one or a plurality of accumulator modules described above and a control system for all the accumulators (BMS) to which all the accumulators are electrically connected by an electric power circuit configured of such that the voltage increases from the electronic modules to the BMS are made by line carrier currents (CPL) on said circuit.
    Each of the electronic modules can be electrically connected to another of the electronic modules by means of one or more so-called redundancy electrical wires.
    Each flange can advantageously integrate into its side wall a connection connection between two redundancy wires, one being directly connected to an electronic module, the other being connected to another electronic module.
    Preferably, the wire connected between the connectors and the other electronic module is fixed, in particular by gluing, along the wall of the accumulator adjacent to that supporting the electronic module.
    The invention also relates in another of its aspects, to a crossing forming a terminal for a metal-ion electrochemical accumulator, produced through an orifice opening out on either side of a wall of the accumulator housing, comprising:
    - an electrically conductive male part, internally comprising a passage, intended to circulate a cooling fluid having circulated along the longitudinal axis of the accumulator, the passage being opening towards the outside of the accumulator;
    - an electrically conductive female part, fitted tightly around a part of the male part, outside the accumulator;
    - two electrically insulating washers, each comprising a support portion in surface support with pressure both against one of the faces of the wall and a guide portion projecting from the support portion and in contact with the edge of the orifice; the bearing portion of a washer being pressed against the female part; the bearing portion of the other washer being pressed against a part of the male part.
    According to an advantageous embodiment, there is also provided a continuous weld bead produced edge to edge between the male and female parts.
    According to an advantageous variant, the male part comprises an annular groove adapted to accommodate an O-ring seal.
    Preferably:
    - the male part is made of pure copper (CuAl), preferably, with a nickel-based surface treatment, or nickel-plated copper or aluminum alloy;
    - the female part is in a grade of aluminum 5754 or copper or nickel-plated copper;
    - the insulating washers is made of polyethrimide (PEI).
    The invention also relates to an accumulator module, comprising at least two accumulators described above, the accumulators being assembled together by means of the bushing forming an output terminal of one of the accumulators screwed to a hollow mandrel of the other of the accumulators, through the bottom of the latter.
    The bushing is preferably screwed into the hollow mandrel according to a tightening torque at least equal to 3 N.m.
    The invention also relates to a battery pack comprising one or more accumulator modules as described above.
    Finally, in another of its aspects, the invention relates to a sub-assembly for a metal-ion electrochemical accumulator, comprising:
    - an electrically conductive part of a crossing forming a terminal of the accumulator, the part internally comprising a passage, intended to open outwards from one of its ends of the accumulator;
    - a mandrel with a longitudinal axis (X) and for winding the electrochemical cell of the accumulator, the mandrel being electrically conductive and internally comprising a passage, intended to open outwards from the accumulator to the other of its ends;
    an electrically insulating element between the electrically conductive terminal part and the electrically conductive winding mandrel, the insulating part comprising a passage opening both into the passage of the terminal part and the passage of the mandrel winding, the passages being intended to circulate a coolant of the accumulator.
    According to an advantageous embodiment:
    - the electrical insulation element comprises a hollow collar extended by a hollow cylinder;
    - The terminal part comprises a widening in diameter extended by a hollow cylinder, one end of which is fitted and fixed in a sealed manner with respect to the cooling fluid, in the hollow cylinder of the electrical insulation element;
    - The mandrel is a hollow cylinder, one end of which is fitted and sealed in relation to the cooling fluid, around the hollow cylinder of the electrical insulation element.
    According to another advantageous embodiment, the terminal piece, the mandrel and the electrical insulation element are assembled together according to a magnetic pulse welding process, or by bonding, or by shrinking, or by brazing.
    Advantageously, the terminal piece comprises a thread intended to cooperate by screwing with another thread for fixing and the electrical output of the accumulator.
    Advantageously also, the mandrel comprises a thread intended to cooperate by screwing with another thread for the fixing and the electrical outlet of the accumulator.
    The mandrel is preferably made of aluminum, preferably made of 99.5% pure aluminum (1050A).
    The invention also relates to a metal-ion battery or accumulator comprising a sub-assembly which has just been described, the terminal piece of which constitutes a passage part of the cover of the accumulator case, and the mandrel of which crosses the bottom. of the case by being welded to it.
    The invention finally relates to an accumulator module, comprising at least two accumulators as above, the accumulators being assembled together by means of the bushing forming output terminal of one of the accumulators screwed to the hollow mandrel of the other accumulators, through the bottom of the latter.
    The bushing is advantageously screwed into the hollow mandrel according to a tightening torque at least equal to 3 N.m.
    detailed description
    Other advantages and characteristics of the invention will emerge more clearly on reading the detailed description of examples of implementation of the invention made by way of illustration and not limitation, with reference to the following figures among which:
    - Figure 1 is a schematic exploded perspective view showing the different elements of a lithium-ion battery,
    FIG. 2 is a front view showing a lithium-ion accumulator 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 cylindrical housing;
    - Figure 4 is a perspective view of a lithium-ion battery according to the state of the art with its rigid packaging consisting of a prismatic housing;
    - Figure 5 is a perspective view of an assembly by means of busbars of lithium-ion batteries according to the state of the art, forming a battery pack;
    - Figure 6 is a schematic perspective view of an example of a module (M) of accumulators according to a first alternative heat transfer circuit according to the invention;
    - Figure 7 reproduces Figure 6 and further shows a sealed heat transfer circuit;
    - Figure 8 is a perspective view of a variant of the module (M) of accumulators according to Figures 6 and 7;
    - Figure 8A is a cross-sectional view along A-A of Figure 8;
    - Figure 9 is a schematic perspective view of an example of a module (M) of accumulators according to the first and a second alternative heat transfer circuit according to the invention;
    - Figure 10 is an axial sectional view of an embodiment of tubes housing the plurality of accumulators of a module (M) according to the first alternative of the invention;
    - Figure 11 reproduces Figure 10 and shows an alternative embodiment with means for centering the tubes;
    - Figure 12 is a perspective view showing another alternative embodiment of the tube centering means;
    - Figure 13 is a schematic perspective view of an example of a plurality of module (M) of accumulators forming a battery pack according to the first alternative of heat transfer circuit according to the invention but according to a mode separate from Figures 5 to9;
    - Figure 14 is a schematic view of a plurality of module (M) of accumulators according to the invention electrically connected in series but with their coolant circuits fluidly connected in parallel;
    FIG. 15 is a schematic view of a plurality of modules (M) of accumulators according to the invention electrically connected in parallel but with their heat transfer circuits fluidly connected in series;
    - Figure 16 is a cross-sectional perspective view of an accumulator according to an advantageous embodiment of the invention;
    - Figure 17 is a detail view in cross section and in perspective of Figure 16, made at a bushing forming an output terminal and a winding mandrel of an electrochemical cell, to which the terminal is fixed according to an advantageous mode of the invention;
    FIG. 18 is a perspective view of an output terminal according to FIGS. 16 and 17;
    - Figure 19 is a perspective view of a mechanical connection piece and electrical insulation between output terminal and mandrel according to Figures 16 to 18;
    - Figure 20 is a perspective view of an accumulator mandrel according to Figures 16 and 17;
    - Figure 21 is a perspective view of a mandrel according to a variant of the invention;
    - Figure 22 is a longitudinal sectional view of a mechanical but electrical insulating assembly according to the invention, between an output terminal and a winding mandrel of an electrochemical battery cell;
    - Figure 23 shows a variant of an assembly according to Figure 22;
    - Figure 24 is a detailed perspective view showing the top of an output terminal according to the invention, formed as a crossing of the cover of an accumulator;
    - Figure 25 shows Figure 17 showing all the elements of the output terminal according to the invention;
    - Figure 26 is a detail view in longitudinal section and in perspective of a mechanical assembly between two adjacent accumulators of the same module according to the invention, the mechanical assembly produced by means of an output terminal according to invention allowing an electrical connection in series of the cells of the accumulators while electrically insulating their respective housings;
    - Figure 27 is a detail view in longitudinal section showing Figure 26;
    - Figure 28 is a cross-sectional view showing two adjacent accumulators mechanically assembled together by being connected in electrical series by means of an output terminal according to the invention;
    - Figure 29 is a perspective view of an example of a current collector ensuring the electrical connection between accumulator cell and output terminal;
    - Figure 30 is a perspective view of an interface piece forming a flange for electrical insulation between accumulators connected in series by the output terminal according to the invention
    FIG. 31 is a detailed view in perspective and by transparency of an accumulator, produced at the top of its housing, FIG. 31 showing the parts of electrical connection between the electrochemical cell of the accumulator and the output terminal, as well as the interface part as it is mounted on top of the battery case;
    - Figures 32 and 33 are front views respectively from below and from above of an insulating collar according to the invention;
    - Figures 32A and 33A are cross-sectional views along A-A of Figures 32 and 33;
    - Figure 34 is a perspective view of an insulating collar according to the invention before its tight mounting on the upper part of the housing of an accumulator;
    - Figure 35 is a detail view in longitudinal section and in perspective of an accumulator with its collar mounted tightly on the upper part of the housing of an accumulator;
    - Figure 36 is a perspective view from the outside of two accumulators assembled together by being connected in electrical series and with an insulating collar between them;
    - Figure 37 is a perspective view of a part of a complete module (M) of accumulators assembled together by being connected in electrical series and with an insulating flange between two adjacent accumulators;
    - Figure 38 is a longitudinal sectional view of two accumulators assembled together by being connected in electrical series and with an insulating collar between them and a heat transfer circuit tube around;
    - Figure 39 is a longitudinal sectional perspective view showing two adjacent accumulators mechanically assembled together by being connected in electrical series by means of an output terminal according to the invention and with an insulating collar between them;
    - Figures 40A and 40B are views respectively in longitudinal section and in perspective showing Figure 39, these figures showing the useful volume of a flange according to the invention;
    - Figures 41A and 41B are views respectively in perspective and in longitudinal section showing Figure 39, these figures showing an alternative embodiment according to which the flange serves as a support for an electronic module in the form of a microcontroller;
    - Figure 42 is a longitudinal sectional view showing Figure 39, this figures showing an alternative embodiment according to which an electronic module in the form of a microcontroller inserted inside the flange;
    - Figure 43 illustrates an equivalent electrical diagram of one or more battery modules according to the invention with a BMS, and microcontrollers supported or inserted in the flanges;
    - Figure 44 is a schematic detail view in section showing the start of an electrical redundancy link with its connection from a microcontroller supported in a flange of an accumulator to a microcontroller of an adjacent accumulator;
    - Figure 45 is a longitudinal sectional perspective view showing two adjacent accumulators mechanically assembled together by being connected in electrical series by means of an output terminal according to the invention and with an insulating collar between them, and a connection electrical redundancy between the microcontrollers of the two accumulators;
    - Figure 46 illustrates an equivalent electrical diagram of one or more battery modules according to the invention with a BMS, microcontrollers supported or inserted in the flanges and the electrical redundancy link;
    - Figure 47 is a block diagram showing the realization of the closed circuit of a heat transfer fluid within one or more accumulator modules according to the invention with expansion tank incorporating a safety device;
    - Figure 48 is a perspective and exploded view of an accumulator output terminal incorporating a safety vent according to the invention;
    - Figure 49 shows Figure 48 and shows the safety vent fixed and in the operating configuration on the output terminal according to the invention;
    - Figure 50 is a perspective view of an advantageous embodiment of a safety vent to be integrated and fixed to an output terminal according to the invention;
    - Figure 51 is a detail view in longitudinal section and in perspective of an accumulator produced at an output terminal incorporating a safety vent according to the invention;
    - Figures 52 to 55 are views from the digital simulation of an example of a battery cooled according to the state of the art in air and according to the heat transfer circuits according to the invention.
    Figures 1 to 5 relate to different examples of Liion accumulators, boxes and bushings forming terminals as well as a battery pack according to the state of the art. These Figures 1 to 5 have already been commented on in the preamble and are therefore not further described below.
    For the sake of clarity, the same references designating the same elements according to the state of the art and according to the invention are used for all of the figures 1 to 55.
    Throughout the present application, the terms "lower", "upper", "bottom", "high", "below" and "above" are to be understood by reference with respect to a Li-ion battery case positioned vertically with its cover on top and an outlet terminal protruding upwards from the outside of the housing.
    FIGS. 6 to 9 show an example of a module M of plurality of Li-ion accumulators A with housings, according to a first alternative of the invention.
    The stack of Al-A4 accumulators aligned one after the other and interconnected in electrical series is housed in a double-walled enclosure 10.
    The Al-A4 accumulators illustrated are cylindrical in size.
    More specifically, the double-walled envelope 10 consists of two concentric tubes 11, 12, arranged coaxially around the accumulators. The space between the inner tube 11 and the outer tube 12 defines a volume of heat transfer fluid over the entire periphery of the battery boxes.
    The envelope 10 may constitute a closed double-walled tank 11, 12 filled with a phase-change material (MCP) of the solid-liquid type. It is thus possible to generate a constant liquid temperature over the entire length of the casing 10, and therefore over all the heights of the Al-A4 accumulators.
    Instead of a closed tank, the casing 10 can be a double-walled conduit, emerging at one of its ends 13 by a supply port 15 of heat transfer fluid and at the other of its ends 14 by a port outlet 16 of the fluid. Thus, it is possible to circulate a heat transfer fluid C1 over the entire periphery of the accumulator boxes, from the inlet orifice 15 to the outlet orifice 16.
    One or more compression elements, such as springs or blades, can be arranged inside the inner tube 11 and at one or both ends 13, 14 of the tube 11 in order to ensure the longitudinal positioning of the together inside the tube while ensuring electrical insulation from the tube which must remain at a neutral potential, i.e. different from the positive pole of the housing or the negative pole of the through terminal lid.
    The inner tube can either be a separate tube 11 of the accumulator housings 6, or be delimited by the lateral envelopes of the housings 6. In other words, when it is a separate tube 11, the accumulators A1-A4 are fitted inside it, preferably with direct contact.
    Conversely, the lateral casings of housings 6 of aligned Al-A4 accumulators can delimit the inner tube 11. This variant allows an inner tube to be eliminated and therefore the thermal resistance between the heat transfer fluid and Al-A4 accumulators to be reduced, this which therefore generates better heat exchanges.
    As shown by transparency in FIGS. 6 to 8, the electrical connection in series is advantageously made by an output terminal 5 which projects from the housing 6 of an accumulator, with the bottom 8 of the housing 6 of an adjacent accumulator and the electrical output of the module M is done on the one hand by the output terminal 5 of the accumulator A4 at one end 13 and by the bottom of the accumulator Al at the other end 14. An advantageous embodiment of the terminal of output 5 according to the invention is described below.
    The supply of heat transfer fluid, which is a cooling fluid (liquid or gas or refrigerant) when it is desired to cool the Al-A4 accumulators in operation, can be done directly with hoses or others which are sleeved then that the 'fixed at the ends 13, 14 of the module. The fixing can be ensured by screwing, welding or brazing.
    Depending on the nature of the heat transfer fluid used (conductive or dielectric), there are different ways of proceeding for electrical connections. Thus, there are several possible variants for removing the connectors and electrically supplying the accumulators A1-A4 inside the double-walled conduit 10.
    If it is a dielectric fluid, it is not problematic if it is found in contact with the output terminals 5 of the accumulator, the connectors can be removed by a tight connection which crosses the double wall 11, 12. An example of a sealed connection sleeve 17 for a dielectric fluid is shown in FIG. 7.
    This sealed connection sleeve 17 longitudinally passing through the interior of one end 13 of the double wall 11, 12.
    As a variant, if one wishes to avoid any contact between the heat transfer fluid and the connectors, one can envisage sleeves which each relate to a fluid collector 18, 19 passing laterally through one end 13, 14 of the double wall. In this case, two sealed closure elements 20, 21 each close longitudinally one end 13, 14 of the double wall.
    Thus, the supply and collection of the heat transfer fluid C1 is done laterally, the heat transfer fluid no longer being in potential contact with the output terminal 5 of the accumulator A4.
    The closing element 20 can also directly constitute one of the two output terminals of the module M. In this case, it is necessary to electrically isolate it from the tubes 11, 12. To do this, as shown in FIGS. 8 and 8A, a block of insulating material 22 is arranged around the terminal 5 and the closure element 20. A similar insulating block, not shown, is arranged at the other end of the module.
    A second alternative according to the invention for managing the thermal of a module M consists in circulating a heat transfer fluid in all of the cores of Al-A4 accumulators.
    According to this second alternative, it is a matter of producing a continuous flow of this fluid through all of the mandrels which have the primary function of serving as the winding core of an electrochemical cell before its housing in a housing. accumulator. In other words, the mandrels are hollow and also serve as a heat transfer fluid circulation conduit, all of the hollows being hydraulically connected in series within the same module M.
    Due to the fact that the two heat transfer fluid circuits are independent within the same module M, it is therefore possible to use one or the other or to combine them, that is to say to have a circulation of heat transfer fluid over the entire periphery of the accumulator housings 6 and an additional circulation of coolant at the heart of the accumulators.
    As symbolized by the arrows in FIG. 9, the invention therefore makes it possible to have a combined circulation of a heat transfer fluid C1 at the periphery of the Al-A4 accumulators with a heat transfer fluid C2 at the heart of the Al-A4 accumulators.
    The heat transfer fluids C1 and C2 can be the same fluid or be distinct. Depending on the geometry and / or the chemistry of the electrochemical cells, it is thus possible to choose a fluid C1 with thermal or dielectric characteristics, different from those of the fluid C2.
    As also symbolized by the arrows in FIG. 9, the circulation of the fluid Cl may be co-current with that of C2 or even in the opposite direction of flow, that is to say in counter-current to C2. This counter-current circulation can make the temperature of Al-A4 accumulators in the same module even more uniform.
    As shown diagrammatically in FIG. 10, a double-walled conduit 10 according to the invention therefore consists of an inner tube 11 either filled with accumulators A1-A4 in contact with its internal wall, or delimited by the lateral envelopes of the housings 6 and an outer tube 12 concentric with the inner tube 11, 6. The annular space E between inner tube 11 and outer tube 12 therefore defines the cross section of the heat transfer fluid Cl. Typically, the annular space E can advantageously vary between 1 mm and 20 mm, depending on the size and power of the batteries.
    In order to ensure that the fluid can flow in the annular space E delimited between these two tubes 11, 12, centering means between them must be provided.
    The centering means can consist of fins or inserts 23 of straight shape, fixed on one at least two tubes 11, 12 which extend along the axis of the tubes by being uniformly angularly distributed as shown in FIG. 11.
    These fins or inserts 23 also have the advantage of being able to increase the surface area for exchange with the heat transfer fluid Cl which will circulate in the annular space E. Typically, by choosing a material constituting the fins 23 which is a good thermal conductor (aluminum, copper, ...), we may be able to multiply the exchange surface between the fluid Cl and the internal tube 11 by a factor of about 1 to 5, and therefore reduce the temperature difference between fluid C and accumulators A1-A4 of the same factor. It goes without saying that care is taken to size the fins or inserts 23 so that they do not obstruct the passage section of the fluid Cl in order to have acceptable pressure drops. In the context of the invention, care must also be taken not to produce a short circuit via the tube if the fins are electrically conductive.
    FIG. 12 shows an alternative embodiment according to which a single helical fin 24 is crimped around the internal tube 6, 11. This helical fin 24 also makes it possible to increase the exchange surface and to intensify the heat exchange, because propeller 24 which also allows the heat transfer fluid to rotate.
    To ensure peripheral circulation around Al-A4 accumulators assembled in modules M according to the invention, it is conceivable to replace the double-walled conduits 10 by a tubular type exchanger 25, such as that shown diagrammatically in FIG. 13.
    In this exchanger 25, a bundle of modules (Ml, M2, M3, M4 ...) of accumulators is housed in a sealed hollow body forming a calender 26 which will act as an external wall for guiding the heat-transfer fluid while the inner wall is provided for each module (M) by a single tube 11 inside which are housed the batteries aligned and electrically connected in series. With such an exchanger 25, there is no longer any peripheral flow in a double wall 10 and the heat transfer fluid travels outside the tubes 11.
    More specifically, the exchanger 25 comprises two tubular holding plates 27 each pierced with a plurality of orifices 28 parallel to each other. The number of ports is equal to that of the plurality of tubes 11 of the modules (M) of accumulators.
    Each of the two ends of each tube 11 is engaged in a retaining orifice 28 of a tubular plate 27 while being tightly fixed to the latter. ;
    The grille 26 is tightly fixed around the tubular plates 27 to delimit the coolant circuit. The grille 26 includes at one of its ends a supply orifice 30 for heat transfer fluid and at the other of its ends an outlet orifice 31 for the fluid.
    In addition, baffles 32 are arranged inside the calender 26 for guiding the flow of the heat transfer fluid Cl. As illustrated, the baffles 32 are constituted by plates extending transversely to the tubes 11 and parallel to the plates tubular ends 27, being regularly spaced along the tubes and closing part of the cross section of the calender, to guide the heat transfer fluid around the tubes 11 of the accumulator modules (Ml, ... M4). The baffles then also make it possible to support the mass of the tubes 11 filled with accumulators (Al-A4) and thus avoid the bending of the tubes 11 under the weight of the accumulators.
    Finally, on either side of the retaining plates 27, two electrical collectors 29 make it possible to house a plurality of electrical connections connected to the plurality of accumulator modules M1-M4 to electrically connect all of these modules to each other.
    Depending on the type of applications, it is also possible to produce the exchanger 25 with circulation at the heart of each of the Al-A4 accumulators of the modules M1-M4, the electrical collectors 29 then also playing the role of fluid collector.
    In other words, the exchanger 25 cooled by the heat transfer fluid C around the accumulators Al-A4 of each module and possibly at the heart of each of them, constitutes in itself, once the electrical connections in series or in parallel between the different modules Ml to M4, a battery pack.
    A module M of accumulators formed according to the invention constitutes an autonomous assembly with a number of X of accumulators in series which one can easily handle, put in place where one wishes to connect fluidly and electrically with other modules accumulators according to the invention.
    Thus, depending on the characteristics of a battery pack that one wishes to obtain, one will electrically connect a number Y of modules M of accumulators to each other.
    All combinations of electrical and fluid connection between several modules according to the invention are possible.
    Depending on the heat dissipated by the accumulators, the desired temperature uniformity from one accumulator to another, the physical properties of the heat transfer fluid used, the M modules are combined in series or fluid parallel. Indeed, the fluid heats up gradually and we can then have temperature differences between the first and the last accumulator of the same module.
    FIG. 14 illustrates a configuration of battery pack P according to which the circulation of the heat transfer fluid Cl and / or C2 is ensured in parallel between all the modules Ml, M2 ... .Mn while they are connected in electrical series with one another.
    FIG. 15 illustrates a configuration of battery pack P according to which the circulation of the heat transfer fluid Cl and / or C2 is ensured in series between all the modules Ml, M2 ... .Mn while they are connected in electrical parallel to each other. A circulation of heat transfer fluid only in series has the advantage of not causing any problem in the distribution of fluid since all the accumulators are in contact with the same flow of fluid, unless the fluid heats up along the flow.
    In order to carry out an electrical mounting in series of several accumulators within the same module which has just been described, one solution consists in connecting them by connecting a terminal 5 to the center of the cover 9 of the casing of an accumulator to the terminal opposite 4 located on the bottom 8 of the housing of an adjacent accumulator.
    To achieve a continuous circulation of heat transfer fluid at the heart of the electrochemical cells of Al-A4 accumulators of the same module M, the inventors have thought of producing a hollow sub-assembly 33 comprising a hollow mandrel 34 and a hollow output terminal part. 5 in the continuity of the hollow mandrel 34. This subassembly must induce a minimum or even no pressure drop for the circulation of the coolant. In addition, it must guarantee a perfect seal with the interior of the accumulator, in order to avoid any contact between the heat transfer fluid and the electrolyte of the accumulator.
    A sub-assembly 33 is shown with its components 5, 34, 43 in FIGS. 16 to 23.
    Figures 16 and 17 show the interior of an accumulator A which integrates such a subassembly 33 within it.
    The hollow mandrel 34 retains its primary function and supports the electrochemical cell C which is wound around during its winding. The diameter of the mandrel 34 thus respects the winding conditions of a cell C in order to generate the desired electrochemical performance of the accumulator.
    To advantageously ensure the electrical and mechanical connection with a terminal 5, the end 35 of the mandrel 34 opposite to that in connection with the terminal 5, includes a thread 35. The threaded mandrel 34 and the bottom 8 of the housing 6 therefore constitute the another terminal 4 of the accumulator, typically the positive terminal in the case of a Li-ion accumulator.
    The part 5, hollow in its center, which forms a male part of the output terminal is shown alone in FIG. 18. It firstly comprises in its upper part a thread 36 adapted to cooperate with the thread 35 of the mandrel 34 of an adjacent accumulator to make the electrical and mechanical connection between two accumulators.
    A groove 37 is produced below the thread 36, so as to be able to accommodate there a seal 38, for example made of PTFE. In the continuity of the groove 37, the part 5 comprises a first enlargement of diameter 39 which serves as the crimping diameter of a female part 50 of the output terminal as described below, and a second enlargement of diameter 40 in the continuity of the first which serves as both a support surface with an electrical insulation washer and a connection surface to a current collector which makes the electrical connection with the cell as described below.
    Finally, in its lower part, the part 5 comprises two diameter reductions 41, 42, the end of which is adapted to be fitted inside the mandrel 34.
    To guarantee the internal polarity of the accumulator A, so as not to create a short circuit and cause thermal runaway, it is imperative to electrically isolate within the sub-assembly 33, the terminal 4 constituted by the hollow mandrel 34 , typically the positive terminal, of the hollow terminal piece 5, typically the negative terminal.
    To do this, the hollow sub-assembly 33 comprises a mechanical connection and electrical insulation part 43 shown in detail in FIG. 19.
    It comprises in its upper part a flange 44 and in its lower part a cylinder 45. The dimensioning of the parts and their positioning are chosen so that the flange 44 extends above the base 52 of current collector 51 described by after.
    This connecting piece 43 being made of electrically insulating material, it is necessary to guarantee a mechanically robust and perfectly sealed assembly of this piece 43 with the terminal piece 5 and the mandrel 34 both made of electrically conductive material.
    Also, the inventors have thought of using the technique of magnetic pulse welding ("Magnetic Puise Welding" in English), which is a process based on the use of electromagnetic forces to weld parts together. Such a method consists in arranging the different parts to be welded in an induction coil but without contact with it. During the welding cycle, a very large amount of electrical energy is released in a very short period of time. Thus, the high energy flow crosses the coil and this current discharge induces eddy currents in the external part to be welded. These two currents create a magnetic field. The repulsion between the two magnetic fields develops a force which gives a very great acceleration to the external part to be welded in direction of the internal part. Such a force pushes the atoms of the materials against each other so that a metallic assembly is obtained between internal and external parts.
    Because the magnetic pulse welding process is a cold welding process, in which the materials to be welded do not reach more than 30 ° C, no area of the parts is affected thermally and the material does not lose its properties . This means that after welding, the parts can be immediately released and implemented. The absence of heat during the welding cycle makes it possible to assemble materials having a very different melting point. In addition, during the magnetic pulse welding cycle, the metal of a part is not melted. Finally, a magnetic pulse weld is stronger than the weakest base metal.
    A hollow sub-assembly 33, produced by a magnetic pulse welding process, guarantees on the one hand the perfect seal between the electrolyte present in the accumulator and the heat transfer fluid which will circulate inside the sub-assembly and on the other hand the perfect electrical insulation between the polarities of the accumulator between the cover and the bottom.
    Other techniques for assembling the sub-assembly 33 by gluing, shrinking or brazing are also possible.
    For the materials of the hollow sub-assembly 33, different combinations can advantageously be envisaged.
    Thus, the male part 5, preferably produced by one-piece machining, can be made of aluminum or copper. More preferably, the material is pure copper (CuAl. For corrosion reasons, a nickel-based surface treatment can be deposited on the surface. The diameter enlargements 39, 40 can be applied to the workpiece 5 by laser welding or shrinking in order to reduce the cost of machining / material Finally, the height of the part 5 is optimized, so as not to machine very long but also in order to reduce material costs.
    The hollow mandrel 34, preferably produced by extrusion, is preferably made of aluminum. More preferably, the material is 99.5% pure aluminum (1050A) which is usually the material of the bucket 7 and the bottom 8 of an accumulator case 6. This provides the best chemical compatibility for welding, in particular by laser, between the mandrel 34 and the bottom 8.
    The electrical insulation and mechanical connection part 43 is preferably made of rigid plastic with very good chemical inertness, and preferably produced by machining or by injection. The part 43 is preferably made of polypropylene (PP) or polyetherimide (PEI), which have the advantage of being resistant with the usual electrolytes of accumulators and an oil as heat transfer fluid while having good mechanical characteristics at the deformation. The part 43 can undergo a coating treatment, for example with a mixture of ferrite and insulating resin, in order to make it ferromagnetic to apply the solder while remaining insulating from a current flow point of view.
    The mechanical clearances during assembly before assembly by welding between the three parts 5, 34, 43 are chosen to guarantee the fitting of the parts together but also to ensure sealing. For example, we can dimension a male piece 5 of copper terminal with a g6 type adjustment on its reduction 41 of diameter equal to 5 mm and an aluminum mandrel 34 of 5 mm internal diameter with an H7 type adjustment in order to allow a tight fitting between the three parts 5, 34, 43 which is possible to perform by hand.
    As shown in Figure 22, the hollow sub-assembly 33 internally defines a continuous and sealed passage of the heat transfer fluid C2 over the entire height of the accumulator.
    To further facilitate the circulation of the heat transfer fluid C2 in the direction shown in FIGS. 22 and 23, it is advantageous to provide the inside of the diameter reduction part 41 at the end thereof with a chamfer 46. By way of example , for the dimensions indicated above, the chamfer 46 is 1 mm high, with an inclination of 45 °.
    In order to guarantee the best possible electrical connection between two accumulators while avoiding any risk of short-circuit and guaranteeing the sealed passage of the heat-transfer fluid to the heart of the accumulators, the inventors have proposed an output terminal in the form of a crossing already described in part above.
    The crossing forming the output terminal is now described as a whole with reference to FIGS. 24 to 28.
    The crossing is made through an orifice 47 opening on either side of a cover 9 of an accumulator housing A.
    The bushing first comprises two identical electrically insulating washers 48, 49. These two insulating washers 48, 49 have the function of ensuring the seal with respect to the electrolyte within the accumulator on which the crossing is made, with respect to the outside of the cover 9 In addition, they provide electrical insulation between the male part 5 of the terminal and the cover 9.
    To do this, each washer has a support portion and a guide portion projecting from the support portion. The bearing portion of the upper washer is in surface support with pressure against the upper face of the cover 9 and its guide portion is in contact with the edge of the orifice 47 of the cover 7. Similarly, the portion of support of the lower washer 49 is in surface support with pressure against the lower face of the cover 7 and its guide portion is in contact against the edge of the orifice 47 of the cover 7.
    The electrically conductive male part 5 is adjusted clamped by its enlargement of diameter 39 in a female annular part 50, opening out at its center, which is also conductive.
    In the assembled configuration, the female annular part 50 is therefore crimped around the enlarged diameter 39 of the male part 5 and presses against the upper insulating washer 48.
    As can be seen in FIG. 24, the different dimensions of the components of the terminal are such that, in this assembled configuration, the thread 36 in the upper part of the male part 5 protrudes beyond the female part 50 and the O-ring sealing 38 is interposed between them.
    Thus, as shown in FIGS. 26 to 28, this female part 50 by its annular surface makes it possible to provide the electrical connection between the terminal 5, 50, typically at the negative pole, of an accumulator A2 and the bottom 8 of the case 6 of the accumulator adjacent Al to the positive pole by a plate ensuring the passage section at high currents.
    The thread 36 is used for connection between the output terminal of an accumulator A2 with the bottom 8 of case 6 of an adjacent accumulator A2. More precisely, the thread 36 which cooperates by screwing with the thread 35 of a hollow mandrel 34 makes it possible to guarantee a high level of tightening, typically of the order of 3N / m between two adjacent accumulators A1, A2, and therefore a resistance less contact, of the order of 12 to 15 mohm.
    The O-ring 38 therefore seals the heat transfer fluid C2 at this threaded junction 35, 36, the tightening of the seal being controlled by the adjustment between the bottom of the groove 37 and the internal diameter of the hollow mandrel 34.
    To proceed with the assembly of a bushing with a cover 9 of an accumulator case, the following steps are carried out:
    positioning of the lower insulating washer 49 around the enlargement of diameter 39 of the conductive male part 5, hollow and opening internally, with the bearing portion of the washer 49 bearing against the enlargement diameter 40 of the room 5;
    - Positioning of the cover 9 with its orifice 47 around the guide portion of the insulating washer 9;
    - Positioning of the upper insulating washer 48 around the enlargement of diameter 39 of the male part 5 with support of the bearing portion of the washer 48 against the cover;
    - crimping of the annular female part 50 around the enlargement of diameter 39 of the male part 5.
    The crimping pressure generates a compression along the X axis of the bushing which is the central axis of the accumulator.
    The inventors carried out different crimping tests by increasing the thickness E of the base of the male part 5 of the terminal according to the invention. This base is formed by the enlargement of diameter 40.
    By definition, the value of the thickness E of the base 40 is all the more important that the diameter 39 of bore 0 is large because the more this diameter increases and, the more the crimping force must be important.
    Another important characteristic to guarantee a robust mechanical connection between male part 5 and female 50, after crimping is the height H of the cylindrical portion of the female part 50 which defines the height of the tight fit. “Robust mechanical connection” is understood to mean, within the meaning of the invention, a connection which makes it possible to meet the required specifications, in terms of mechanical resistance of this type of terminal which constitutes a terminal or output terminal of an accumulator, it i.e. a tensile strength, a tightening torque strength, a vibration resistance, a mechanical shock resistance, a resistance to temperature variations (-40 ° C / + 75 ° C), ...
    To overcome a possible problem of relative expansion between male parts 5 and female 50 of the terminal according to the invention, in particular in the case of the use of an accumulator module in an environment with large temperature variations, advantageously, provision can be made to produce a continuous weld bead S, edge to edge between these parts 5, 50, preferably by laser welding.
    With this weld bead S, it protects against the heating of the thread 36 of the male part, under the passage of strong currents which could lead to a degradation of the axial tightening of the washers 48, 49, due to the start of sliding of the female part 50 on the axis of the male part 5.
    The female part 50 can be of 5754 aluminum grade or copper or nickel-plated copper. Aluminum 5754 has the advantages of having very good mechanical characteristics and remains intact when pressure is applied to its surface, especially during crimping according to the invention. The nickel-plated copper is advantageously of the same nature as that defined for a conventional copper negative terminal, which makes it possible to maintain an identical interface for a user.
    The male part 5 is preferably made of nickel-plated copper because it is compatible with the materials constituting the electrochemical core of a Li-ion accumulator (chemistry of electrode materials, electrolyte based on LiPF6, etc.). But, as already mentioned, the male part can just as easily be made of aluminum.
    The insulating washers 48, 49 are advantageously made of polyethrimide (PEI).
    As shown in Figures 27 and 28, the dimensioning of the different parts of the output terminal, and in particular the height H1 of the female part 50 ensures a minimum separation distance d between two housings 6 of adjacent accumulators A1, A2 . Typically, this distance d is at least equal to 1 mm, preferably between 1 and 5 mm.
    To guarantee good electrical conduction between the electrode within the electrochemical bundle C of a given polarity, in particular the negative polarity, and the output terminal according to the invention, there is provided a metal current collector 51 illustrated as as in figure 29.
    This current collector 51 comprises a flat base 52 which is welded at the top of the electrochemical bundle C to the metal strip supporting the active material of the electrode and a tongue 53 folded back on itself and welded to the enlargement of diameter 40 of the male part 5 of the terminal. This base 52 and tongue 53 therefore provide electrical continuity between the electrode and the output terminal, of given polarity.
    As mentioned, a cooling / reheating circulation mode consists in circulating the heat transfer fluid on the periphery of the Al-A4 accumulators within the same module, with direct contact on the side envelopes of their housings, that is to say, by dispensing with an additional inner tube 11.
    In addition, as explained above, the dimensioning of an output terminal according to the invention of an accumulator and its fixing by screwing to the bottom of the housing of an adjacent accumulator allow a minimum separation distance d between these two accumulators assembled.
    The inventors have thought of taking advantage of this minimum separation space to define an interface piece 54 which allows both:
    - ensure instead of a free space of material, electrical insulation between two adjacent accumulators electrically connected and assembled within the same module;
    - to guarantee additional safety in centering and mechanical maintenance between the two accumulators;
    - to maintain a clearance with an external tube 12, in order to define with the skin of the accumulators connected to each other, that is to say with their lateral casings of housings, a double-walled conduit 10 for circulation of heat-transfer fluid.
    This interface part 54 forming a flange is shown as such in FIG. 30. It firstly comprises a flat base 55 pierced with a through opening 56 whose diameter is adapted to that of the female part 50 which comes stay there.
    The flat base 55 is surrounded by an annular wall 57 which comprises a plurality of spacer tabs 58 distributed uniformly at the periphery of the annular wall 57 according to a spacing pitch e5. These tabs 58 have the function of guaranteeing a spacer, that is to say of guaranteeing a fixed spacing with an external tube 12 in which are housed the Al-A4 accumulators assembled together of the same module M.
    The side wall 57 is further shaped to delimit an annular groove 59 of complementary shape with that of the top of a battery case 6, that is to say complementary to the upper shape of the side casing 7 and the cover 9 which is welded to it.
    Thus, an interface piece or flange 54 is adapted to be fitted by its annular groove 59 on the inner rim of the cover 9 of the housing 6 and the top of its lateral envelope 7.
    This fitting can be done manually and the dimensions of the collar 54 advantageously allow tightening during assembly.
    As an example, for an accumulator of cylindrical format 50125, the dimensions of the flange 54, referenced in Figures 32 to 33A, are those of Table 1 below.
    TABLE 1
    Diameter Height / spacing Radius of curvature 01 = 52 mm el = 3.5 mm R 0.50 02 = 50.5 +/- 0.1 mm e2 = 2 mm 03 = 20.5 mm e3 = 4.5 mm 04 = 46 mm + 0.1 mm e4 = 8.5 mm 05 = 44 mm e5 = 6 mm
    With a cover 9 which usually has an internal diameter of 46 +/- 0.1 mm, the tightening obtained with the flange 54 according to the dimensions indicated in the table is 0.2 to 0.25 mm for the minimum cover dimension , or from 0 to 0.05 mm for the maximum dimension of the cover.
    In other words, it guarantees tightening of the flange when it is placed on the cover 9.
    The collar 54 can advantageously be produced by injection of a plastic, in particular a PA6-6 or a polyoxymethylene (POM) such as that sold under the brand Delrin®.
    Figures 34 and 35 show the flange 54 respectively before and once it is tightened in place on an accumulator case 6.
    Thus, once placed on an accumulator A1, the collar 54 makes it possible to guide the adjacent accumulator A2, during the electrical connection between terminal 5 and hollow mandrel 34. The guidance therefore takes place via this collar 54 and the outer periphery of the bottom 8 of the accumulator box.
    Figures 36 and 37 show the outside of part of a module M with the Al-A4 accumulators electrically connected together, assembled by their terminals 5 and hollow mandrel 34, and guided and spaced from each other by the flanges 54 arranged individually between them.
    As shown in FIG. 38, this assembly is in turn inserted into a tube 12 which will constitute the external tube of the double-walled conduit 10 for the circulation of the heat-transfer fluid C1 at the periphery of the accumulators, the double-wall being delimited internally by the side envelopes of the accumulator boxes 6. During this insertion, the guidance of the Al-A4 accumulators is ensured by the outside diameter of the flange 54, that is to say by the outside diameter 01 of the spacer tabs 58.
    In addition to the fact that the outer tube 12 must of course have a greater internal diameter, in order to allow easy fitting of the assembled Al-A4 accumulators, this internal diameter is also dimensioned as a function of the external diameter of the flange 54 and the thicknesses of the legs. spacer 58, so as to control the pressure losses of the heat transfer fluid while taking care to block the accumulators and withstand in particular vibrational stresses.
    The additional function of the flange 54 which has just been described is to electrically isolate the accumulators A1-A2 from each other, during and, once the connection by the output terminal 5 has been made. FIG. 39 illustrates this function well where it is clearly seen that, by the shape of the collar 54, any contact between two housings 6 of adjacent accumulators, and more particularly between the cover 9 of one and the bottom 8 of the other is prohibited.
    The inventors have also thought of assigning the collar 54 another function. In fact, as shown in FIGS. 40A and 40B, the inventors have defined a flange 54 which, once the assembly between adjacent accumulators has been carried out, leaves a volume V free between the base 55 of the flange 54 and the bottom 8 of the housing 6 adjacent.
    Thus, they thought of taking advantage of this available volume V to house an electronic module 60 or microcontroller adapted to manage the electrical management of each accumulator independently of the others.
    Indeed, in a battery pack, it is interesting to be able to monitor each accumulator in order to raise the voltages of these to the BMS of the pack, and this with the double objective of detecting a possible fault and of balancing in tension the set of accumulators.
    More specifically, each electronic module 60 or microcontroller may include at least one memory, a communication module adapted to receive and / or transmit data from and / or to the outside of each accumulator and a processor adapted to receive and / or transmit at least data from and / or to the communication module.
    The inventors therefore thought of using the base 55 of the collar 54 as a support for an electronic module 60, as shown in FIGS. 41A and 41B. The electronic module 60 can be fixed by gluing or other means on the base 55.
    The power supply to an electronic module 60 is advantageously provided by the terminals of an accumulator. As shown in FIGS. 41B, it is thus possible to pass an electrical supply wire 61 of a polarity through the flange 54 to connect it electrically to the cover and another electrical supply wire 62, of opposite polarity to connect it. electrically to the female part 50 of the terminal. Thus, the power supply wires 61, 62 independently supply the electronic module 60 with the current delivered by the accumulator.
    FIG. 42 shows a variant according to which the electronic module 60 is embedded by thermoforming in the thickness of the base 55 of the collar 54.
    FIG. 43 shows the equivalent electrical diagram of a module M of accumulators A1-A2 connected to a BMS 70, and each supplying an electronic module 60. The voltage rises from the electronic modules 60 to the BMS are made by carrier current CPL on the power circuit of accumulators A1-A2.
    A variant of this embodiment consists in connecting all the electronic modules 60 together so that the BMS 70 can communicate directly with these electronics, in order to have physical redundancy on the rise in voltages.
    This redundancy is ensured by connection wires 64, 65 between modules 60. As shown in FIGS. 44 and 45, a first connection wire 64 is connected from module 60 to a connector 60 arranged in the thickness of the outer edge 57 of the flange 54 then a second connecting wire 65 is preferably fixed by gluing to the lateral envelope 7 of the case 6 of the accumulator, in order to connect each of the connections to the flanges 54. With these connecting wires 64, 65, very little or no additional pressure drop is introduced into the heat transfer fluid Cl.
    Figure 46 shows the equivalent electrical diagram with redundancy by wires 63, 65 and connections 64.
    Having defined a module M of accumulators Al, A2, ... Am electrically connected in series and cooled / heated by means of a circulation of heat transfer fluid Cl and / or C2, and a battery pack consisting of a plurality of modules Ml, M2 ... Mn, the inventors looked into the control of safety, in particular with regard to the generation of gases or the propagation of thermal runaway.
    They then thought of being able to continuously degas the gases resulting from the abnormal electrochemical functioning of the accumulators via the coolant circuit and take the opportunity to recover and quantify these gases.
    Thus, they defined the fluidic system as shown schematically in Figure 47.
    A pump 80 operating continuously supplies the heat transfer circuit circuit C1 and / or C2 permanently during the operation of a module Ml or of a battery pack P consisting of a plurality of modules Ml, M2, M3. .
    An expansion tank 90 is installed on this circuit. The gases generated in the heat transfer circuit are therefore recovered in the sky from the expansion tank 90. Thus, in the event of gas overpressure, the gas sky fills and beyond a predetermined overpressure threshold, this can open automatically the electrical circuit on the scale of an Ml module or of the battery pack P and thus guarantee permanent operating safety. In addition, a safety device can be provided to protect the expansion tank from overpressure in the gaseous air, in particular a valve, and / or a regulating device controllable by the BMS.
    To achieve the opening of the electrical circuit, the inventors have thought of implanting a rupture membrane or rupture seal directly within each output terminal of an accumulator according to the invention.
    More specifically, as shown in FIGS. 48 to 51, the male part 5 is pierced at its diameter reduction 41 with a through hole 66 which joins the interior of the part.
    On this through hole 66 is fixed, preferably by welding, a rupture membrane 67 which forms a vent. This rupture membrane 67 is gas permeable and impermeable and compatible with a coolant. An advantageous type of membrane is described in patent application WO 1996/016288 A1.
    As shown in FIG. 49, the vent may consist of a membrane in the form of a disc 67 made of gas-permeable material and impermeable to the cooling fluid, typically according to application WO 1996/016288 A1 and a crown made of metal 68 welded to part 5 and which sandwiches the membrane 67 on the through hole 66.
    As is clearly visible in FIG. 51, the membrane 67 is arranged on the male part 5 of the terminal of the accumulator, so that it is in the empty volume of the latter, that is to say above the base 52 of the collector 51, where the gases are formed during the electrochemical operation.
    Thus, this membrane 67 also constitutes a safety vent, in the event of gas overpressure. Indeed, in this case, the rupture lines 69 formed in the membrane 67 break and the latter tears. The rupture value can be set at a maximum gas pressure value of around 12 bar.
    Consequently, in the event of a large quantity of gas generated in any of the accumulators of a module M or of a battery pack P, this causes an overpressure of gas in the accumulator and thus causes the rupture of the membrane 67 and therefore when the accumulator is over-pressurized by the heat transfer fluid C2, preferably an oil.
    The overpressure gases arrive in the sky of the expansion tank and the triggering threshold is exceeded, which leads to the opening of the electrical circuit in series, either of the module concerned, or of the entire battery pack.
    The inventors carried out calculations with thermal simulation to highlight the relevance of the various types of cooling / heating according to the invention.
    For cylindrical format accumulators and with standard sizes, typically respectively 18650, 26650, 50125, it is possible to calculate the ratio between the exchange surface and the volume of the accumulator.
    The higher the ratio, the more easily the electrochemical cell of the accumulator is cooled (or heated). This ratio goes from 250 to 95 when you go from an 18650 format accumulator to a 50125 format accumulator.
    Therefore, with relatively large accumulators, the heat exchange coefficient must be increased to compensate for this reduction in exchange surface area per unit of volume.
    In the examples indicated in table 2 below, the format used for the accumulators is the format 50125, that is to say a diameter of 50 mm and a height of 125 mm.
    To compare the different cooling modes according to the state of the art and according to the invention, an internal heat source equivalent to an IC discharge is generated, that is to say about 13 Watts.
    The simulated accumulator according to the invention has a hollow mandrel, that is to say a perforated accumulator over the entire height of its central axis, with an outside diameter equal to 9 mm and an inside diameter of 7 mm.
    Note that for example 1, the accumulator has a hollow mandrel in which the air is trapped without any real cooling effect, given the small volume.
    It is also specified that for the simulations, the accumulators do not include an external box but because of the thinness of the latter, it would have little or no influence on the simulations.
    TABLE 2
    Examples Type of cooling Average volume temperature (° C) Affected figure Comparative example according to the state of the art Free air with thermal coefficient h equal to 10 W / m2 / K and Outdoor temperature of 25 ° C 57.8 Figure 52 Example 1 according to the invention Free air and dielectric oil circulation only in the hollow mandrel 43.6 Figure 53 Example 2 according to the invention Circulation of dielectric oil both in the hollow mandrel and on the periphery of the accumulator 29.1 Figure 54 Example 3 according to the invention Dielectric oil circulation only on the periphery of the accumulator 30.8 Figure 55
    From this table 2, it appears that a liquid cooling on the periphery of the external walls of an accumulator makes it possible to greatly reduce the average temperature of the accumulator, since by comparison with the example according to the state of the art which implements natural cooling in the open air, the difference is about 30 ° C. over the average temperature.
    In addition, the addition of an oil circulation to the heart of the accumulator, that is to say over its entire central height in the hollow mandrel makes it possible to reduce the temperature differences in the heart of the accumulator.
    The invention is not limited to the examples which have just been described; one can in particular combine together characteristics of the examples illustrated within variants not illustrated.
    Other variants and improvements can be envisaged without departing from the scope of the invention.
    If in all the detailed examples, the Al-A4 accumulators illustrated are of cylindrical format, it is possible to envisage carrying out all of the characteristics of the invention with accumulators of prismatic format.
    Also, all of the detailed examples have been described, one or more circulations of heat transfer fluid for cooling or homogenizing the temperature of the accumulators A1-A4 of the same module M and for several modules ΜΙ.,. Μη electrically and fluidly connected to each other. The heat transfer fluid can also be a heating fluid for preheating the accumulators or for maintaining the accumulators at constant temperature. This can be of interest for certain cell chemistries which typically require an operating temperature well above room temperature.
    Furthermore, for the production of the hollow sub-assembly 33 according to the invention, the magnetic pulse welding process has been described for welding between the electrical insulating part 43 and on the one hand the male part 5 of a terminal and on the other hand the mandrel 34 which forms the opposite polarity terminal. It is entirely possible to envisage other joining techniques between these different parts 5, 34, 43 such as hooping and / or bonding.
    权利要求:
    Claims (13)
    [1" id="c-fr-0001]
    1. Feedthrough forming terminal for a metal-ion electrochemical accumulator, produced through an orifice (47) opening on either side of a wall (9) of the accumulator housing, comprising:
    - an electrically conductive male part (5), internally comprising a passage, intended to circulate a cooling fluid having circulated along the longitudinal axis of the accumulator, the passage being opening towards the outside of the accumulator;
    - an electrically conductive female part (50), fitted tightly around a part of the male part, outside the accumulator;
    - two electrically insulating washers (48, 49), each comprising a support portion in surface support with pressure both against one of the faces of the wall and a guide portion projecting relative to the support portion and in contact with the edge of the orifice (47); the bearing portion of a washer (48) being pressed against the female part; the bearing portion of the other washer (49) pressing against a part of the male part.
    [2" id="c-fr-0002]
    2. Bushing according to claim 1, further comprising a continuous weld bead (S) made edge to edge between the male and female parts.
    [3" id="c-fr-0003]
    3. bushing according to claim 1 or 2, the male part (5) comprising:
    - a thread (36) intended to cooperate by screwing with another thread (35) for fixing and electrical outlet of the accumulator;
    a first enlargement diameter (39) below the thread (36) and which serves as a crimping diameter for the female part (50), and
    - A second enlargement of diameter (40) in the continuity of the first which serves as both a support surface with the electrical insulation washer (49) and a connection surface to a current collector (51) intended to make the electrical connection with the electrochemical cell of the accumulator.
    [4" id="c-fr-0004]
    4. Bushing according to one of the preceding claims, the male part (5) comprising an annular groove (37) adapted to accommodate an O-ring seal (38).
    [5" id="c-fr-0005]
    5. Bushing according to one of the preceding claims, the male part (5) being made of nickel-plated copper or an aluminum alloy.
    [6" id="c-fr-0006]
    6. Bushing according to one of the preceding claims, the female part (50) being of an aluminum grade 5754 or of copper or nickel-plated copper.
    [7" id="c-fr-0007]
    7. Bushing according to one of the preceding claims, the insulating washers (48, 49) being made of polyethrimide (PEI).
    [8" id="c-fr-0008]
    8. Metal-ion battery or accumulator comprising a housing (6) with a cover (9) through which a bushing according to any one of the preceding claims is made.
    [9" id="c-fr-0009]
    9. Metal-ion battery or accumulator according to claim 9, the cover being made of aluminum, such as aluminum 1050 or 3003.
    [10" id="c-fr-0010]
    10. Li-ion battery or accumulator according to claim 8 or 9, accumulator in which:
    - the material of negative electrode (s) is chosen from the group comprising graphite, lithium, titanate oxide Li ^ iOsOn;
    - the material of positive electrode (s) is chosen from the group comprising LiFePCU, LiCoO2, LiNio.33Mno.33Coo.33O2.
    [11" id="c-fr-0011]
    11. Module (M) of accumulators, comprising at least two accumulators (Al, A2) according to one of claims 8 to 10, the accumulators being assembled together by means of the bushing forming the output terminal of a ( Al) of the accumulators screwed to a hollow mandrel (34) of the other (A2) of the accumulators, through the bottom (8) of the latter.
    [12" id="c-fr-0012]
    12. Module (M) of accumulators according to claim 11, the bushing being screwed into the hollow mandrel according to a tightening torque at least equal to 3 N.m.
    [13" id="c-fr-0013]
    13. Battery pack comprising one or more modules (M) of accumulators according to claim 11 or 12.
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    同族专利:
    公开号 | 公开日
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    FR3075477B1|2021-07-30|
    EP3499603B1|2020-02-12|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP2002231298A|2001-02-02|2002-08-16|Mitsubishi Materials Corp|Battery and battery pack using it|
    WO2012115131A1|2011-02-24|2012-08-30|新神戸電機株式会社|Secondary battery, and lithium ion battery|
    US20150118547A1|2012-04-24|2015-04-30|Commissariat A L'energie Atomique Et Aux Energies Alternatives|Bushing Forming a Terminal for a Lithium Storage Battery and Related Storage Battery|
    FR2928773A1|2008-03-14|2009-09-18|Peugeot Citroen Automobiles Sa|ELECTRIC ENERGY ACCUMULATING DEVICE AND TRAIN COMPRISING A PLURALITY OF SUCH DEVICES.|DE102019118162A1|2019-07-04|2021-01-07|F.E.R. Fischer Edelstahlrohre Gmbh|Cell connectors for cells and cell modules and battery modules with cells|
    DE102019118160A1|2019-07-04|2021-01-07|F.E.R. Fischer Edelstahlrohre Gmbh|Cell with electrical energy storage and housing|
    CN112582731A|2019-09-30|2021-03-30|比亚迪股份有限公司|Battery module|
    法律状态:
    2018-12-31| PLFP| Fee payment|Year of fee payment: 2 |
    2019-06-21| PLSC| Publication of the preliminary search report|Effective date: 20190621 |
    2019-12-31| PLFP| Fee payment|Year of fee payment: 3 |
    2020-12-28| PLFP| Fee payment|Year of fee payment: 4 |
    2021-12-31| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1762152|2017-12-14|
    FR1762152A|FR3075477B1|2017-12-14|2017-12-14|TRAVERSE FORMING TERMINAL FOR METAL-ION ELECTROCHEMICAL ACCUMULATOR, ASSOCIATED ACCUMULATOR|FR1762152A| FR3075477B1|2017-12-14|2017-12-14|TRAVERSE FORMING TERMINAL FOR METAL-ION ELECTROCHEMICAL ACCUMULATOR, ASSOCIATED ACCUMULATOR|
    EP18212072.5A| EP3499603B1|2017-12-14|2018-12-12|Crossmember forming a terminal for a metal-ion electrochemical storage cell, associated cell|
    JP2018233406A| JP2019110122A|2017-12-14|2018-12-13|Bushing for forming terminal for metal ion electrochemical accumulator battery, and relevant accumulator battery|
    KR1020180162485A| KR20190072482A|2017-12-14|2018-12-14|A bushing forming a terminal for a metal-ion electrochemical accumulator, associated accumulator|
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