Accumulator battery pack, comprising devices for passive magnetic between accumulators and busbars, and, where appropriate, passive shunt of one or more accumulators in case of failure of these ones

Abstract

A battery pack wherein each battery is mechanically and electrically connected by a magnetic device to a busbar. In case of failure of any accumulator, it is disconnected completely passively because its failure generates an inactivation of the magnetic device. The disconnection causes the gravity drop of the accumulator and the possibly completely passive implementation of an accumulator shunt.

Claims

1. A battery pack comprising: a plurality of electrochemical batteries or accumulators, each comprising: a housing or a flexible packaging, a first output terminal and a second output terminal of an opposite polarity to the first output terminal; at least one of the output terminals comprising: an electrically conductive part, a magnetic lock comprising a permanent magnet; at least one ferromagnetic part secured to an electrical connecting busbar, called busbar, forming a closure plate of a magnetic circuit with the magnetic lock of the output terminal; the battery pack being configured such that: i/ in normal operation of the accumulator, magnetic attraction force of the permanent magnet of the output terminal on the closure plate of a first busbar, in a closed magnetic circuit configuration, ensures the mechanical and electrical connection between the output terminal and the first busbar, ii/ upon a failure of the accumulator provoking an overheating thereof, the permanent magnet of the output terminal heats up and at least to a temperature from which it loses its magnetic properties, to the point of mechanical disconnection between the output terminal and the first busbar, which causes the accumulator to drop through gravity.

2. The battery pack according to claim 1, comprising: at least one flexible electrically conductive blade fixed at one of its ends to another busbar or other portion of busbars, comprising a permanent magnet; the battery pack being configured so that: during step i/, the permanent magnet of the flexible blade is repelled by that of the output terminal such that the flexible blade cannot be in electrical contact with the first busbar, during step ii/, because of absence of magnetic repulsion of a faulty accumulator having fallen, the electrical connection between the first and the other busbar through respectively the flexible blade, which realizes hence a shunt of the accumulator.

3. The battery pack according to claim 1, wherein a Curie temperature of the permanent magnet is chosen to be between a value close to 90% of a self-heating temperature and a value close to 110% of a thermal runaway temperature of the pack accumulators.

4. The battery pack according to claim 1, wherein the permanent magnet is a sintered magnet or a plasto-magnet.

5. The battery pack according to claim 4, wherein the sintered magnet or the plastomagnet is based on rare earths, including samarium-cobalt or neodymium-iron-boron, or is made of ferrite.

6. The battery pack according to claim 4, wherein the sintered magnet is made of aluminum-nickel cobalt alloy.

7. The battery pack according to claim 1, wherein at least one of the two output terminals comprises at least one second ferromagnetic part arranged around or inside the electrically conductive part, the second ferromagnetic part being closed by the closure plate in a configuration of closure of the magnetic circuit.

8. The battery pack according to claim 7, comprising at least a third ferromagnetic part arranged around the second ferromagnetic part forming an annular housing in which is housed a plasto-magnet, coil being arranged inside the first ferromagnetic part.

9. The battery pack according to claim 1, wherein each ferromagnetic part is made of soft iron.

10. The battery pack according to claim 2, wherein each flexible blade is made of copper-beryllium.

11. The battery pack according to claim 1, wherein each electrically conductive part of each lock is made of the same material as an accumulator output terminal.

12. The battery pack according to claim 1, wherein each electrically conductive part of each lock is made of aluminum or of copper.

13. The battery pack according to claim 1, comprising an electrically conductive crinkle washer or tooth lockwasher, arranged such that, in the configuration of closure of the magnetic connection circuits, it ensures an electrical contact between one of the output terminal equipped with a lock and one of the busbars.

14. The battery pack according to claim 2, comprising an electrically conductive crinkle washer or tooth lockwasher, arranged such that, in a configuration of closure of the magnetic shunt circuits, it ensures an electrical contact between the blade and one of the busbars.

15. The battery pack according to claim 13, wherein each washer is made of copper-phosphorus alloy.

16. The battery pack according to claim 1, wherein the first or second output terminals are arranged on one face of a case or the flexible packaging, while, respectively, the second or the first output terminal is arranged on an opposite face of the case or the flexible packaging, the accumulator being arranged horizontally so that its fall by gravity along ii/ takes place perpendicularly to its longitudinal axis.

17. The battery pack according to claim 1, wherein the first and second output terminals are both arranged on a same face of the housing or the flexible packaging, the accumulator being arranged vertically so that its fall by gravity along ii/ takes place along its longitudinal axis.

18. The battery pack according to claim 1, wherein each accumulator comprises a battery management system fixed on the housing or the flexible packaging of the accumulator and electrically powered by the latter.

19. The battery pack according to claim 1, comprising a honeycomb structure comprising a plurality of recesses each suitable for receiving an accumulator falling by gravity; each recess being capable of being filled with a heat transfer liquid at least once the fall of the accumulator carried out, in order to cool the latter.

20. The battery pack according to claim 19, wherein the heat transfer liquid is that of a cooling circuit of the battery pack, or a liquid independent of said cooling circuit, a supply of which in each housing is controlled by a battery management system of the battery pack, or a liquid resulting from a change of state of a phase change material obtained by heating of the accumulator.

21. The battery pack according to claim 1, each electrochemical battery or accumulator comprising: a negative electrode(s) material chosen from the group comprising graphite, lithium, titanium oxide Li4TiO5O12; a positive electrode(s) material chosen from the group comprising LiFePO4, LiCoO2, LiNi0.33Mn0.33Co0.33O2.

Description

DETAILED DESCRIPTION

(1) Other advantages and features of the invention will be better revealed on reading the detailed description of exemplary implementations of the invention given in an illustrative and nonlimiting manner with reference to the following figures in which:

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

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

(4) FIG. 3 is a perspective view of a lithium-ion accumulator according to the state of the art with its rigid packaging composed of a housing of cylindrical form;

(5) FIG. 4 is a perspective view of a lithium-ion accumulator according to the state of the art with its rigid packaging composed of a housing of prismatic form;

(6) FIG. 5 is a perspective view of an assembly by means of busbars of lithium-ion accumulators according to the state of the art, forming a battery pack;

(7) FIGS. 6A and 6B are longitudinal cross-sectional views respectively illustrating the magnetic disconnection and connection of a device according to the invention, intended to ensure the mechanical and electrical connection/disconnection between an output terminal of a low-current accumulator, typically lower than 1 A, and a busbar;

(8) FIGS. 7A and 7B are longitudinal cross-sectional views respectively illustrating the magnetic disconnection and connection of a device according to the invention, intended to ensure the mechanical and electrical connection/disconnection between an output terminal of a high-current accumulator, typically higher than 1 A, and a busbar;

(9) FIGS. 8 and 8A are respectively front and side views of an electrically conductive crinkle washer ensuring the electrical contact between busbar and electrically conductive part either of the output terminal or linked thereto, in a device according to FIGS. 7A and 7B;

(10) FIG. 9 is a longitudinal cross-sectional schematic view of a variant of the device according to FIGS. 7A and 7B;

(11) FIG. 10 is a longitudinal cross-sectional schematic view of an advantageous embodiment of the device according to FIGS. 7A and 7B, according to which control of the connection/disconnection between magnetic parts by coil is possible;

(12) FIG. 11 is a longitudinal cross-sectional schematic view of a variant of the advantageous embodiment of the device according to FIG. 10;

(13) FIG. 12 is a schematic longitudinal sectional view of an advantageous embodiment of the device which is a concrete representation of the mode of FIGS. 7A and 7B;

(14) FIG. 13 is a schematic view in longitudinal section of an advantageous embodiment of the device which is an alternative to that of FIG. 10;

(15) FIG. 14 is a variant of FIG. 12;

(16) FIG. 15 is a variant of FIG. 13;

(17) FIG. 16 is a longitudinal cross-sectional schematic view of an advantageous embodiment of a power current device, with incorporation of a part thereof in a bushing forming an output terminal of a metal-ion accumulator;

(18) FIG. 17 is a perspective schematic view of the male part with its cap blocking a bushing according to FIG. 17;

(19) FIG. 18 is a perspective schematic view of a variant embodiment of a male part of a bushing according to the invention;

(20) FIG. 19 is a perspective schematic view of a metal-ion accumulator of prismatic format incorporating two output terminals with magnetic lock according to the invention on the cover of the accumulator housing;

(21) FIG. 20 is a perspective schematic view of a metal-ion accumulator of cylindrical format incorporating two output terminals with magnetic lock according to the invention one on the cover of the accumulator housing, the other on the bottom;

(22) FIG. 21 is a side and partially cross-sectional schematic view of a metal-ion accumulator according to FIG. 16, with the ferromagnetic parts inserted into busbars forming closure plates of the circuit with the magnetic locks incorporated in the output terminals of the accumulator;

(23) FIG. 22 is a perspective and partially exploded schematic view of an existing metal-ion accumulator of prismatic format with an interface adapter incorporating magnetic locks according to the invention;

(24) FIG. 23 is a perspective schematic view of the accumulator with its interface adapter according to FIG. 22, in its configuration installed on the housing of the accumulator;

(25) FIG. 24 is a partial longitudinal cross-sectional schematic view of an accumulator and its interface adapter according to FIGS. 22 and 23 facing ferromagnetic parts inserted into busbars forming closure plates of the circuit with the magnetic locks incorporated in the adapter;

(26) FIG. 25 is a perspective and exploded schematic view of another interface adapter incorporating a magnetic lock according to the invention;

(27) FIG. 26 is a perspective and partially exploded schematic view of an existing metal-ion accumulator of prismatic format with an interface adapter according to FIG. 25 to be fixed, fitted or screwed around an output terminal of the accumulator;

(28) FIG. 27 is a partial longitudinal cross-sectional schematic view of an output terminal of an accumulator around which is fitted an interface adapter facing a ferromagnetic part which are inserted into a busbar forming a closure plate of the circuit with the magnetic lock incorporated in the adapter;

(29) FIGS. 28A and 28B go back to the device of FIG. 10 and illustrate the steps of a first mode of blowing out electrical arcs likely to occur upon magnetic disconnection;

(30) FIGS. 29A and 29B respectively go back in bottom view to FIGS. 28A and 28B and illustrate the locations of the points of creation of the electrical arcs and their convergence upon extinction;

(31) FIGS. 30 and 31 are respectively exploded and assembled perspective schematic views of an advantageous variant of closure plate and electrical contacts producing the extinction of the arcs according to the first mode;

(32) FIG. 32 illustrates, by side and plan schematic views, the formation of the electrical arcs with a closure plate and contacts according to FIGS. 30 and 31;

(33) FIGS. 33A and 33B go back to the device of FIG. 10 and illustrate the steps of a second mode of extinction of the electrical arcs likely to occur upon magnetic disconnection;

(34) FIG. 34 is a longitudinal cross-sectional schematic view of a device with flexible blade magnetic shunt according to the invention, intended to ensure the shunt between two busbars; the blade being fixed with electrical connection to one of the busbars;

(35) FIG. 35 is a longitudinal cross-sectional schematic view of an advantageous embodiment of the device according to FIG. 35, according to which the shunt is duplicated, but with a fixing of each flexible blade produced on an insulating part;

(36) FIG. 36 is a longitudinal cross-sectional schematic view of a variant of the magnetic shunt device according to FIG. 35;

(37) FIG. 37 is an electrical diagram illustrating a device with magnetic shunt according to the invention, with reversing switch function in order to shunt an electrical circuit comprising a metal-ion accumulator;

(38) FIG. 38 is a longitudinal cross-sectional schematic view of a device with rigid blade magnetic shunt according to the invention, intended to produce a reversing switch between two busbars as according to FIG. 37;

(39) FIGS. 39A to 39E are longitudinal cross-sectional schematic views showing the different steps of operation of a device both for magnetic connection/disconnection between the two output terminals of an accumulator and two busbars and for magnetic shunt of the disconnected failing accumulator;

(40) FIGS. 40 and 41 are perspective views of a connection/disconnection and magnetic shunt device according to FIGS. 39A to 39E, in a battery pack;

(41) FIGS. 42A and 42B are longitudinal cross-sectional schematic views showing the different steps of operation of a variant of a device both for magnetic connection/disconnection between the two output terminals of an accumulator and two busbars, incorporating a passive detection of the magnetic disconnection by reed switch;

(42) FIG. 43 is a longitudinal cross-sectional schematic view of a device both for magnetic connection/disconnection between an accumulator and two busbars and for magnetic shunt of the disconnected failing accumulator, the device consisting of a reversing switch and operating by disconnection of just one of the two accumulator output terminals;

(43) FIGS. 44 to 46 illustrate, by perspective schematic view, the components at different stages of their assembly of a battery pack with several branches in series of accumulators in parallel within each branch, each accumulator being connected to two busbars by means of a magnetic connection/disconnection device according to the invention;

(44) FIGS. 47 and 48 illustrate, by perspective view, a battery pack assembled as according to FIGS. 40 to 42 and which further incorporate a magnetic shunt device between two busbars;

(45) FIGS. 49 and 50 illustrate, by perspective view, a battery pack assembled as according to FIGS. 44 to 45 and which further incorporate a reversing switch between two busbars;

(46) FIGS. 51 to 53 illustrate, by perspective schematic view, the components at different stages of their assembly of a battery pack with several branches in series of accumulators in parallel within each branch, each accumulator being connected to two busbars by means of a magnetic connection/disconnection device according to the invention and the battery pack incorporates, on each branch, a magnetic shunt device between two busbars;

(47) FIG. 54 is a perspective view of a magnetic shunt device according to FIG. 36, within the battery pack of FIG. 53;

(48) FIGS. 55 to 57 illustrate, by perspective schematic view, the components at different stages of their assembly of a battery pack with several branches in parallel of accumulators in series within each branch, each accumulator being connected to two busbars by means of a magnetic connection/disconnection and magnetic shunt device according to the invention, as illustrated in FIGS. 39A to 39E;

(49) FIG. 58 is a perspective schematic view of a honeycomb structure with individual recesses for unitary metal-ion accumulators of one and the same battery pack;

(50) FIG. 59 is an exploded schematic view of a battery pack incorporating a honeycomb structure according to FIG. 56 and an electrically insulating substrate incorporating busbars connected magnetically to the accumulators.

(51) FIGS. 1 to 5 relate to different examples of Li-ion accumulators, of housings and bushings forming terminals and a battery pack assembled by busbars according to the state of the art. These FIGS. 1 to 5 have already been commented on in the preamble and are not therefore discussed further hereinbelow.

(52) In the interests of clarity, the same references denoting the same elements according to the state of the art and according to the invention are used for all the FIGS. 1 to 59.

(53) Throughout the present application, the terms “lower”, “upper”, “down”, “up”, “below” and “above” are to be understood with reference to an Li-ion accumulator housing positioned vertically with its cover on the top and an output terminal-forming bushing protruding upward out of the housing.

(54) FIGS. 6A and 6B show an example of a magnetic connection/disconnection device 10 according to the invention, intended to ensure the mechanical and electrical connection/disconnection between an output terminal of a low-current metal-ion accumulator and a busbar.

(55) The device 10 here comprises a magnetic lock 11 comprising a permanent magnet 12, for example made of neodymium-cobalt, housed inside a cavity 13 formed in a ferromagnetic part 14, for example made of soft iron. This ferromagnetic part is linked electrically to the output terminal which is not represented here.

(56) Another ferromagnetic part 15, also made of soft iron, is inserted into an insulating substrate 16 incorporating a busbar which is not represented here, and in contact with its electrically conductive part. This other plate 15 forms a closure plate of a magnetic circuit with the magnetic lock 11.

(57) The closed magnetic circuit is illustrated in FIG. 6B: the passage of the current C is made through ferromagnetic parts 14, 15 and the magnetic flux F generated by the permanent magnet 12 circulates in closed loop both in the magnet 12 and in the ferromagnetic parts 14, 15.

(58) Thus, in closed configuration, the closure plate 15 closes the ferromagnetic part 14 to allow a good circulation of the magnetic flux F generated by the magnet. This magnetic circuit exhibits a good magnetic permeability and its closure allows a significant force between the two subassemblies, and therefore guarantees a mechanical connection between the output terminal and the busbar while allowing the electrical contact between them.

(59) In the example illustrated, the closure plate 15 is a solid plate. It is also perfectly possible to consider a closure plate in the form of a ferromagnetic washer which therefore, although hollowed internally, closes a magnetic circuit with the ferromagnetic part 14.

(60) Since the power electrical current is not very intense, it can pass through the ferromagnetic material of the parts 14, 15 which ensures, in this configuration, the electrical conduction and the electrical contact between the two subassemblies of the device. Here, the closure plate 15 must be in direct electrical contact with the bottom ferromagnetic part 14 to allow an electrical conduction of the power current.

(61) FIGS. 7A and 7B illustrate a magnetic connection/disconnection device for high power currents, typically higher than 1 A. In this case, the electrical conduction parts which ensure the passage of the power current and the quality of the electrical contact become important parameters.

(62) Electrically conductive parts are therefore added. First of all, the top ferromagnetic part 15 is directly inserted into the electrically conductive busbar B1. The ferromagnetic part 15, typically made of soft iron, can be inserted by force-fitting or screwing or riveting to the busbar B1, typically made of copper.

(63) Next, the bottom ferromagnetic part 14 is fixed, typically by fitting, into the cavity of an electrically conductive part 17. These two electrically conductive parts B1, 17 are electrical conductors of good quality, typically made of copper or aluminum. Since the resistivity of these conductors is very much lower than that of the ferromagnetic materials of the parts 14, 15, particularly the soft iron, most of the power current will pass through these conductors B1, 17.

(64) In FIG. 7B, the magnetic circuit is closed: the circulation of the power current C passes into through the conductive parts B1, 17. The magnetic flux F of the permanent magnet is enclosed by the magnetic circuit to maximize the magnetic forces.

(65) This FIG. 7B shows the presence of a small air gap e between ferromagnetic parts 14, 15, which does indeed very slightly reduce the connection force but advantageously makes it possible to allow a functional play between these parts.

(66) Furthermore, an electrically conductive tooth lockwasher or crinkle washer 18 is arranged around the top ferromagnetic part 15. In the example illustrated, the ferromagnetic part 15 protrudes relative to the busbar B1 and the tooth lockwasher 18 is arranged around the protruding part of the part 15. Preferably, this washer 18 is made of copper-phosphorus alloy.

(67) This washer 18 makes it possible to guarantee a good electrical contact. Indeed, a good electrical contact requires a significant contact surface and a force to compensate for the surface irregularities. The tooth lockwasher 18 makes it possible to establish several clearly defined points of contact by concentrating the force and by compensating for the mechanical plays.

(68) The protuberances 19 of the washer 18 make it possible to establish several mutually parallel points of contact, which reduces the overall electrical resistance between the conductive parts B1, 17.

(69) An exemplary advantageous form of tooth lockwasher according to the invention 18 is shown in FIGS. 8 and 8A.

(70) Examples of dimensioning of tooth lockwashers 18 according to FIGS. 8 and 8A are indicated in the table below. The washers are shown here as circular but other forms can be envisaged, typically square or rectangular, depending on the form of the terminal.

(71) TABLE-US-00001 Load (reference value) V (mm) D (mm) h (mm) Compressed Compressed Internal External t (mm) Free Deformation height Load Deformation height Load diameter Tolerance diameter Tolerance Thickness position F (mm) h-F (N) F (mm) h-F (N) 3 +0.2 3.6 0 0.05 0.5 0.1 0.4 0.35 0.3 0.2 0.77 0 4.2 −0.2 0.73 1.96 4 +0.3 5 0 0.7 0.2 0.5 0.47 0.4 0.3 0.91 0 6 −0.3 0.87 1.62 5 7 0.60 1.11 8 0.69 1.25 10 0.75 1.42 10 5.23 15.33 12 5.10 19.00 8 10 1.88 4.93 12 2.93 8.72 16 2.84 11.00 10 12 1.03 2.71 14 1.31 4.46 16 1.76 5.82 12 14 0.69 1.71 15 0.98 2.58 17 1.20 3.58 16 +0.5 18 0 0.15 1.5 0.5 1.0 1.33 1.0 0.5 2.82 0 20 −0.5 2.56 5.95 28 4.28 12.61 20 24 1.43 3.31 28 2.34 5.94 22 28 1.48 3.76 30 1.74 4.59 25 +0.9 30 +0.9 0.2 3.0 1.0 2.0 5.40 2.0 1.0 8.78 0 35 0 8.20 16.25 30 35 2.92 5.77 38 4.30 9.29

(72) A variant of the device 10 is shown in FIG. 9: the bottom ferromagnetic part 14 previously described is eliminated. The magnetic flux F of the permanent magnet 12 is enclosed here in air, which means a greater dimensioning thereof to exert the same connection force as that of FIGS. 7A and 7B. The permanent magnet can for example occupy all the cavity of the conductive part 17, as shown in FIG. 9.

(73) All the connection devices 10 which have just been described cannot be disconnected without outside intervention and therefore do not allow for dismantling between accumulator output terminal and busbar in live voltage/current conditions.

(74) To resolve this problem, the device 10 is modified to be controlled by the supply of a current, as shown in FIG. 10.

(75) Here, an electrically insulating mandrel 20 surrounds the permanent magnet 12, and an electrically conductive wire forming a coil 21 is wound around the insulating mandrel. The mandrel 20 can for example be made of insulating plastic, typically a thermoplastic of polyethylene type, and the coil wire can be made of copper.

(76) The device 10 is thus configured such that:

(77) i/ when the coil 21 is not initially electrically powered, the magnetic attraction force of the permanent magnet 12 on the closure plate 15, in the closed magnetic circuit configuration, maintains the mechanical connection between busbar B1 and conductive part 17, and therefore between busbar B1 and the output terminal. The electrical contract between them is produced through the washer 18.

(78) ii/ when the coil 21 is electrically powered in a given direction, it produces a magnetic field opposite to that of the permanent magnet 12, to the point of cancelling the attraction force of the permanent magnet, which provokes the mechanical disconnection between busbar B1 and conductive part 17, or busbar B1 and output terminal. The electrical contact between them is eliminated.

(79) This embodiment is also advantageous because it is possible to temporarily reinforce the attraction force of the permanent magnet 12 by injecting into the coil a current in the direction opposite to that of the phase ii/, which creates a magnetic field in the same direction as that of the permanent magnet 12. Thus, it is possible to more accurately control the closure between conductive parts B1, 17 or simply facilitate it.

(80) Instead of a coil 21, it is possible to install an electrical heating resistor 22 as shown in FIG. 11.

(81) More specifically, this heating resistor 22 surrounds, for example, the permanent magnet 12 and can be surrounded by a thermal insulation 23, whose function is to concentrate toward the permanent magnet 12 the heat produced by the heating resistor 22. Preferably, the thermal insulation 23 can be held by an electrically insulating mandrel 20 like that described above. Other geometrical configurations can be envisaged provided that the magnet is heated sufficiently.

(82) A permanent magnet 12 is sensitive to the temperature and loses its magnetic properties (becomes amagnetic) beyond a critical temperature called Curie temperature. This temperature depends on the materials chosen for the permanent magnet and can vary from 100° C. to more than 250° C. In the context of the invention, the Curie temperature of the permanent magnet is chosen to be between a value close to 90% of the self-heating temperature (T1) and a value close to 110% of the thermal runaway temperature (T2) of the pack accumulators.

(83) Thus, when it is electrically powered, the heating resistor 22 locally heats up the permanent magnet 12 dimensioned for its temperature to exceed the Curie temperature.

(84) Since the magnet 12 no longer exerts attraction force, the mechanical and electrical disconnection occurs between conductive parts B1, 17. The demagnetization of the permanent magnet is definitive and therefore the disconnection according to this variant is too.

(85) The electrical consumption required by the powering of the coil 21 or the electrical heating resistor 22 of a device 10 is very low, which is advantageous for a metal-ion accumulator which is intrinsically electrically autonomous.

(86) Instead of an electrical heating resistor 22, the magnet can be heated up by the accumulator itself. Indeed, in the case of a metal-ion accumulator, its core temperature in thermal runaway mode is compatible with a permanent magnet demagnetization temperature. Thus, the electrical disconnection will be able to be obtained passively by virtue of the thermal runaway of the failing accumulator.

(87) Several types of permanent magnets 12 exist and can be used for the devices described. The ferrite magnets or samarium cobalt are very powerful (strong coercive field) and are those used in the devices described above. These magnets with high performance (potentially expensive) are necessary in the design of a device according to the invention because the permanent magnet is of low volume.

(88) Thus, the geometries shown in the devices previously described are schematic for illustrative purposes.

(89) In practice, a permanent magnet 12 must advantageously be very thin: in fact, it behaves like an air gap e in the magnetic circuit C, and this gap must be as small as possible so that the flow and therefore the effort is maximum. Also, the diameter of the permanent magnet 12 is limited by the reduced device size.

(90) FIG. 12 shows a type of permanent magnet 12 made of ferrite or cobalt samarium such that it can be concretely produced in the form of a disk and arranged in a device according to the invention, intended for the passage of strong currents. In this FIG. 12, it can be seen that the ferromagnetic cavity piece is replaced by a ferromagnetic piece 14 under an adapted shape, i.e. with a central wall at the upper end of which the magnet 12 in the form of a disc is supported. The ferromagnetic part is preferably hollowed out between its central wall and its empty peripheral wall to gain mass.

(91) By way of example, the inventors have made a prototype of a samarium-cobalt magnet 12 in the form of a disk of a thickness of 1 mm and 10 mm in diameter, intended for an output terminal as a device connection/disconnection of approximately of 20 mm in diameter and 20 mm in height. The induction of such a magnet is 1.1 Tesla and the connection force obtained with this magnet 12 is 18N.

(92) As a comparative example, by calculation, a permanent magnet 12 with a diameter of 10 mm and a height of 10 mm only generates a connection force of 0.5 N.

(93) These sintered permanent magnets 12, high performance, are ideal for the applications sought in the context of the invention.

(94) On the other hand, they can be expensive and the shaping that can be achieved with sintered ferromagnetic materials is limited to simple shapes, such as plates, discs, rings of small size.

(95) This is why the inventors have thought of arranging a plasto-magnet in place of a permanent magnet sintered ferrite or samarium-cobalt.

(96) An example of a plasto-magnet arrangement in a connection device 10 according to the invention is shown in FIG. 13.

(97) In this FIG. 13, the annular-shaped plastomagnet 120 which is arranged on the periphery of the contact with the magnetic circuit F made with two distinct ferromagnetic parts 14, 140 which form between it the annular volume in which is housed the plasto-magnet 120. The plastomagnet 120 thus has the shape of a cylinder of small thickness and high height.

(98) A mechanical connection piece 100 may be force-fitted using a press or be welded to the interface between the two ferromagnetic parts 14, 140. Care is taken to ensure compatibility between the materials of the different parts, during their assembly.

(99) As can be seen in this FIG. 13, the magnetic flux F is horizontal at the level of the plastomagnet 120.

(100) Such a plasto-magnet 120 is advantageous because it allows to have a low air gap while benefiting from a large annular volume, and therefore to allow this less powerful magnet solution than the sintered magnets 12.

(101) FIG. 14 shows an advantageous embodiment of the ferromagnetic part 14 with a magnet 12 in the form of a disk as in FIG. 12.

(102) The ferromagnetic part 14 is made with a shoulder to obtain a difference in height 141 which allows both to obtain a magnetic contact zone and to establish a good electrical contact via an elastic washer 18 between the two parts 14, 15 of the magnetic casing, that is to say on the external magnetic circuit C. The arrangement of the washer 18 makes it possible not to add an air gap in the overall magnetic circuit which would be detrimental to the mechanical strength (reduction of the force).

(103) In this configuration, the elastic washer 18 allows a point electrical contact with a sufficient contact pressure. The washer 18 may be coated with one or more suitable contact materials, typically based on a silver coating, to improve the contact resistance and prevent oxidation.

(104) The permanent magnet 12 in the configuration of FIG. 14 is preferably a sintered magnet.

(105) Thus, the configuration of FIGS. 13 and 14 is advantageous because the magnetic circuit consisting of ferromagnetic parts 14, 15, typically made of soft iron, is highly electrically conductive and can pass a high intensity current through the device, via of the conductive elastic washer 18. This therefore ensures good electrical conduction between the closure plate and the magnetic circuit.

(106) We can also consider passing a strong current through a non-magnetic carcass as shown in FIG. 15.

(107) In this FIG. 15, the current no longer passes through the ferromagnetic parts 14, 15 but through the non-magnetic carcass constituted by the parts 17, B1 which are made of copper, for example.

(108) It should be noted that in this configuration of FIG. 15, the mechanical connection piece 100 can be omitted because the electrical conduction part 17 mechanically holds the various elements in its cavity.

(109) The magnetic connection/disconnection devices which have just been described can be partly incorporated directly in the accumulator output terminals.

(110) The aim of this incorporation is to produce a magnetic lock between at least one accumulator output terminal and one busbar, the lock comprising a permanent magnet and a control coil cooperating with a magnetic closure plate.

(111) As will emerge hereinbelow, a magnetic lock is incorporated in an output terminal and the closure plate is on the side of the busbar. Except for the configurations in which an electrical shunt of the accumulator is sought, it is also perfectly possible to consider incorporating the lock on the side of the busbar and the magnetic closure plate in the output terminal of an accumulator.

(112) An exemplary embodiment of an output terminal 5 according to the invention formed by a bushing is shown in FIG. 16.

(113) The bushing 5 is produced through an orifice emerging on either side of the cover 9 of the housing 6 of an accumulator A, which comprises two opposite faces.

(114) The bushing 5 comprises an electrically conductive female part 24, and an electrically conductive male part 17 which comprises the cavity 25 in which the permanent magnet 12 is housed and which is closed by a blocking cap 26 which is also electrically conductive.

(115) The cavity 25 also houses the ferromagnetic part 14 which here complements the permanent magnet 12 to form the magnetic lock.

(116) A portion of the male part 17 is tightly fitted into a blind hole of the female part 24.

(117) Two electrically insulating washers 27, 28 each comprise a bearing portion surface-bearing with pressure against one of the faces of the cover 9 and a guiding portion protruding relative to the bearing portion and in contact with the edge of the orifice.

(118) Furthermore, each of the conductive portions 17, 24 comprises a bearing portion surface-bearing with pressure against a bearing portion of the washers 27.

(119) As shown in FIG. 16, in closed configuration of the magnetic circuit, the magnetic flux F circulates in a loop in the terminal 5 through the ferromagnetic part 14 and the ferromagnetic part 15 inserted into the busbar B1, which guarantees the mechanical connection between terminal 5 and busbar B1. Simultaneously, the circulation of the power current C takes place from the busbar B1 through the cap 26 and the male part 17 of the terminal via the tooth lockwasher 18.

(120) FIG. 17 shows in detail the conductive male part 17 whose cavity 25 houses the permanent magnet 12 and which is closed by the cap 26, in particular fixed by welding. The cap 26 is preferably made of the same material as the male part 17. The thickness of this cap has to be defined according to the air gap desired with respect to the application.

(121) Although not represented, a coil 21 or an electrical heating resistor 22 for the magnetic disconnection of the terminal 5 can be housed in the cavity 25.

(122) A through-orifice 29 provided in the male part 17 makes it possible to pass through an electrical wire powering such a coil or electrical heating resistor.

(123) Instead of a conductive male part 17 with a quasi-blind cavity 25 apart from a through-hole 29 as illustrated in FIG. 17, it is possible to produce the conductive male part 17 with one or more slots 170 on its periphery as shown in FIG. 18. This variant is advantageous because, on the one hand, it allows for a weight-saving for the part 17 and, on the other hand, it allows the possibility of passing the wire powering the coil or electrical heating resistor at several points.

(124) FIG. 19 shows a metal-ion accumulator A of prismatic format whose two output terminals 4, 5, both arranged on the cover 9 of the housing 6, incorporate the magnetic lock with permanent magnet 12. Preferably, each magnetic lock comprises a ferromagnetic part 14 and a coil 21 or electrical heating resistor 22 for the possible disconnection of the accumulator from busbars B1 and/or B2.

(125) Thus, in closed configuration of each of their magnetic circuits, each of the two output terminals 4, 5 is magnetically locked respectively to a busbar B1 and/or B2.

(126) As can be seen in this FIG. 19, the tooth lockwashers 18 can be mounted directly on the output terminals 4, 5.

(127) The electrical powering of a coil 21 or heating resistor 22, with a view to the magnetic disconnection between an accumulator A and the busbars B1 and/or B2, can be produced from the power of the accumulator A or from another accumulator of a battery pack, by a BMS which makes it possible in particular to first detect the failure of the accumulator.

(128) As shown in FIG. 19, such a BMS 30 can be fixed directly onto the cover 9 of the housing and powered directly by wires passing into the through-orifice 29 of the male parts 17 of the terminals 4, 5.

(129) FIGS. 20 and 21 illustrate a metal-ion accumulator A of cylindrical format with the two output terminals 4, 5 which incorporate the magnetic lock with permanent magnet 12, one being arranged on the cover 9 of the housing 6, and the other, opposite, on the bottom of the housing 6.

(130) When wanting to implement the magnetic connection/disconnection devices 10 in existing accumulators, it is possible to incorporate the latter in interface adapters 40 as illustrated in FIGS. 22 to 24.

(131) Such an interface adaptor 40 comprises, first of all, a body 41 of a form preferably at least partly complementary with the bottom 8 or the cover 9 of the housing of the metal-ion accumulator. This body 41 is then mounted by fitting onto the bottom 8 and/or the cover 9.

(132) In the embodiment illustrated in FIGS. 22 to 24, the body 41 comprises two through-recesses 42 inside each of which an output terminal 4, 5 of the metal-ion accumulator can be housed. The body is insulating or electrically insulated from one of the 2 terminals.

(133) Two magnetic locks 11 each comprising a permanent magnet 12 surrounded by an insulating mandrel 20 with its wound coil 21, are incorporated in the body 41. The body 41 can be overmolded around the magnetic locks 11.

(134) The magnetic locks 11 are, here, arranged at the lateral ends of the interface adapter 40, on the outside and side-by-side with the output terminals 4, 5.

(135) The electrical connections between the output terminals 4, 5 and the busbars B1 and/or B2 opposite are ensured by electrically conductive parts 43 each suitable for being fixed with electrical contact to an output terminal of the accumulator. Furthermore, to guarantee an optimal electrical contact, two electrically conductive tooth lockwashers 18 are arranged on either side of a part 43.

(136) A BMS 30 can be inserted inside the body 41 of the interface adapter 40. This BMS 30 is connected to the two magnetic locks 11 and to the output terminals 4, 5 by conductive tongues 31, 32.

(137) The side-by-side arrangement of the magnetic locks 11 and of the output terminals 4, 5 with an interface adapter 40 makes it possible to obtain a higher contact pressure upon a shunt by lever effect, and between the accumulator and the busbars B1 and/or B2 by virtue of the magnetic surfaces available between magnetic locks 11 and ferromagnetic parts 15 which can be greater.

(138) The interface adapters 40 according to FIGS. 22 to 24 can be adapted to all existing accumulator types, whatever the mechanical architecture of the terminals.

(139) Moreover, an interface adapter 40 adds an extra thickness, which can make it possible to better manage the forces involved at the interface between accumulator and busbars.

(140) Another type of interface adapter 40 is shown in FIGS. 21 to 23.

(141) This interface adapter 40 comprises an enclosure 44 made of electrically insulating material, for example produced in insulating plastic material. The enclosure can also be made of conductive material, taking care to manage the different insulations required between parts at different potentials such as between terminals and housing for example. The form of the enclosure is matched to the form of the terminal which can be cylindrical, parallelepipedal or another form.

(142) The enclosure 44 comprises an open central opening 45, which is adapted to be fixed, fitted or screwed or welded around an output terminal of an accumulator A and a cavity 46 suitable for housing a magnetic lock 11 according to the invention, with at least one ferromagnetic part 14 of complementary form which is fitted inside the cavity 46.

(143) A blocking cap 47 closes the enclosure 44 housing the magnetic lock 11.

(144) In the embodiment illustrated in FIG. 27, the interface adapter 40 incorporates a magnetic lock 11 comprising a permanent magnet 12 surrounded by an insulating mandrel 20 with its wound coil 21.

(145) The interface adapter 40 is, here, arranged around an existing output terminal formed by a bushing 5, advantageously produced according to the teaching of the patent application FR2989836.

(146) Thus, the bushing 5 is produced through an orifice emerging on either side of the cover 9 of the housing 6 of an accumulator A.

(147) The bushing 5 comprises an electrically conductive female part 24, and an electrically conductive male part 17 of which a portion is tightly fitted into a hole of the female part 24.

(148) Two electrically insulating washers 27, 28 each comprise a bearing portion, surface-bearing with pressure against one of the faces of the cover 9 and a guiding portion protruding relative to the bearing portion and in contact with the edge of the orifice.

(149) Furthermore, each of the conductive parts 17, 24 comprises a bearing portion, surface-bearing with pressure against a bearing portion of the washers 27.

(150) In this configuration of FIG. 27, the magnetic lock 11 is arranged concentrically around the output terminal 5.

(151) The assembly between interface adapter 40 and output terminal according to the concentric configuration of FIG. 27 can be done by force-fitting or welding or screwing around the output terminal 5 provided in the latter case with an external threading not represented.

(152) Here also, the interface adapters 40 according to FIGS. 25 to 27 can be adapted to all existing accumulator types, whatever the mechanical architecture of the terminals. In particular, these annular adapters 40 can be implemented with lead accumulators whose packaging is made of electrically insulating plastic material. The illustration is of an accumulator with rigid housing. This type of adapter is applied also to the accumulators with flexible packaging.

(153) The magnetic disconnection which has just been described with no other measure can create electrical arc problems for currents of high power.

(154) Indeed, the connection/disconnection of electrochemical accumulators that are charging can lead to the occurrence of an electrical arc at their connections. This arc is very hot, typically several thousands of degrees, which can lead to a runaway of the chemistry and therefore thermal runaway of the battery. This arc is all the more problematical when a metal-ion accumulator is operating in direct current mode, the absence of natural passage of the current through 0 does not necessarily allow for the rapid extinction of the arc.

(155) A first solution for achieving a rapid extinction consists in elongating the electrical arc by using the magnetic fields. The elongation of the arc will increase the exchange surface with the ambient medium and will lead to the cooling of the arc. As the temperature of the arc decreases, its resistance increases until the current becomes nil and the medium becomes insulative.

(156) A first magnetic elongation device is illustrated in FIGS. 28A, 28B and 29A, 29B.

(157) The magnetic connection/disconnection device 10 here necessarily incorporates an electrically conductive tooth lockwasher 18 around the ferromagnetic part 15.

(158) Thus, the electrical contact is made between the conductive tooth lockwasher 18 and a conductive contact of the conductive part 17, which is of cylindrical revolution in the example illustrated. The contact takes place at multiple points of contact.

(159) When the contact opens during the disconnection, several electrical arcs will be triggered at these different points of contact (FIGS. 28A, 29A).

(160) The current in these arcs, which behave as electrical conductors, is in the same direction. These electrical arcs will therefore be attracted according to the Laplace law, which will deform them as shown in FIG. 28B and, thereby, elongate the path and increase the exchange surface with the ambient medium to achieve the extinction of the arcs.

(161) Through the choice of dimensioning of the tooth lockwasher 18, it is ensured that the arcs are sufficiently close to one another, typically a few mm, in order for the Laplace force between the arcs to be sufficient.

(162) A second magnetic elongation device is illustrated in FIGS. 30, 31 and 32. This second device can be complementary to the first device of FIGS. 28A and 28B.

(163) Here, the ferromagnetic part 15 is produced with notches 150, for example V-shaped, when seen from above.

(164) An electrical contact washer of particular form 50 is provided. This washer 50 is in the form of a ring linked electrically to one of the busbars.

(165) The washer 50 is provided with flexible barbs 51 on its internal periphery, each arranged in a notch 150 of the ferromagnetic part 15.

(166) In the configuration of closure of the magnetic connection circuit, each barb 51 is in electrical contact with the conductive part 17 of an output terminal 4 or 5. In fact, the flexible barbs 51 are a little depressed by virtue of their elasticity to compensate for the plays and obtain the desired contact pressure.

(167) Upon the mechanical disconnection between output terminal and busbar, with elimination of the electrical contact between washer 50 and output terminal, electrical arcs between barbs 50 and conductive part 17 of the output terminal will be created. These arcs will generate magnetic fields which will deform the arcs toward the closure ferromagnetic part 15, which will thus cool them until they are extinguished.

(168) More specifically, upon the opening of the contact, electrical arcs will occur as previously which will generate magnetic fields particularly in the ferromagnetic part 15 in proximity. A Laplace force F will be exerted between each electrical arc and this magnetic field which is channeled by the part 15 of very much higher permeability than that of the air.

(169) As previously, the electrical arc will be deformed inward and will be attracted toward the ferromagnetic part 15. The latter, being a good conductor of heat relative to the air, will absorb a large portion of the thermal energy of the arc and will cool it very strongly, leading to its extinction. There may even be a local melting of this closure part 15, which will absorb a considerable energy (slow liquefaction, even vaporization, heat). Care of course must be taken to dimension the parts to compensate for the gradual wear possibly induced by the absorption of the thermal energy of the arc.

(170) A second solution for achieving a rapid extinction consists in generating, at the moment of the occurrence of the electrical arc, a gas under pressure at the center of the contact which will drive the latter outward. The arc is thus elongated outward to cool it and to blow it out.

(171) An arc extinguishing device based on the blowing of pressurized gas is illustrated in FIGS. 33A and 33B. To do this, a part 52 made of electrically insulating material, having a low vaporization point typically lower than 250° C., for example a thermoplastic material of polyethylene type, is arranged at the center of the magnetic lock on top thereof. The melting point of this part 52 should preferably be lower than the Curie temperature of the permanent magnet to be able to blow out the arc without damaging the magnetic properties of the magnet.

(172) Upon the occurrence of the electrical arc, this part 52 with low melting point will be vaporized under the effect of the heat generated by the arc and thus generate gas locally under pressure. Indeed, since the heating due to the arc is rapid, the pressurized gas generated does not have time to be dissipated. This pressurized gas will drive the arc outward from the electrical contact and thus elongate it leading to its extinction (FIG. 33B).

(173) The part 52 with low melting point can be arranged in the air gap, between magnetic lock 11 and ferromagnetic part 15, inside the washer 18. It is possible to provide for this part 52 to constitute, with the insulating mandrel 20 for winding of the coil 21, one and the same part.

(174) FIG. 34 shows an example of magnetic shunt device 60 according to the invention, intended to ensure a shunt within a battery pack and to thus ensure a continuity of operation thereof.

(175) The shunt device 60 comprises a flexible electrically conductive blade 61, fixed at one of its ends to a fixing point 62 on a conductive part of one of the busbars. The blade 61 can be made of copper-beryllium.

(176) At the other end of the flexible blade 61 there is inserted a magnetic lock 11 which comprises a conductive cavity 17 within which is housed a ferromagnetic part 14 which itself houses a permanent magnet 12 and a coil 21 around the magnet 12.

(177) In open position, as represented, the elasticity of the conductive blade needs to be sufficient to compensate for the attraction of the magnet to the ferromagnetic plate on the fixed part, such that the device remains open.

(178) When wanting to close the contact between conductive parts 17, B1, a current is applied in the coil 21 in the appropriate direction, such that the magnetic field generated by the coil reinforces that of the permanent magnet 12. The force generated by the magnetic field of the coil and the magnet combined must then be greater than that of the flexible blade 61. The contact can then be closed and its magnetic locking performed by the magnetic lock 11 with the fixed ferromagnetic part 15.

(179) When the current controlling closure in the coil 21 is cut, the permanent magnet 12 can on its own ensure that the closure is maintained because the air gap between the magnetic lock 11 and the ferromagnetic part 15 is reduced, which implies a magnetic locking force greater than that of the flexible blade 61. The shunt device 60 then remains in closed position, even in the absence of current in the control coil.

(180) To open the shunt device 60, an opposite current must be injected into the coil 21, such that the magnetic field generated thereby is opposite to that of the permanent magnet 12 and cancels the resulting field. When the maintaining force due to this resultant field becomes lower than that of the flexible blade 61, the shunt device 60 can open. The current controlling opening in the coil can then be cut because the blade 61 reverts to the initial position, that is to say that the magnetic attraction force of the magnet 12 is lower than the opening force of the blade 61.

(181) FIG. 35 illustrates a variant which has just been described according to which the shunt device 60 is duplicated apart from the fixing of the blades: two flexible blades 61 are each fixed at one of their ends to an electrically insulating fixing point and incorporate, at the other of their ends, a magnetic lock 11. The operation of the duplicated shunt device 60 is identical to that described with reference to FIG. 34.

(182) Furthermore, the duplicated shunt device 60 advantageously makes it possible to produce the simultaneous disconnection of the two terminals 4, 5 of an accumulator, whereas in the example of FIG. 34, a single terminal 5 is affected by the lock system, the other terminal being linked for example by a flexible cable 63 to the busbar B2.

(183) Another variant of the shunt device 60 is illustrated in FIG. 36: the magnetic locks 11 are, here, inserted into the fixed bottom part, the conductive parts forming the cavities housing the permanent magnets 12, coils 21 and ferromagnetic parts 17 then being produced in the busbars B1, B2 or in conductive parts linked thereto. This variant of FIG. 36 can make it possible to simplify the connecting of the control coils to the electronic control unit, in particular the BMS of an accumulator.

(184) FIGS. 37 and 38 show an example of magnetic shunt device 70 according to the invention, intended to constitute a reversing switch within a battery pack and to ensure not only a continuity of operation thereof but also to shunt a circuit of one or more accumulators.

(185) As illustrated in FIG. 38, the reversing switch device 70 comprises a rigid blade 71 articulated at its center by an articulation 72. The articulation 72 of this rigid blade does not make it possible to simply produce a power electrical connection of quality. Also, the current can be brought to this blade 71 using a metal braid 73, preferably made of copper electrically spot welded to improve this electrical link.

(186) The rigid blade 71 incorporates, at each of its ends, a ferromagnetic part 15, each intended to close a magnetic circuit with one of the magnetic locks 11 arranged in the bottom part of the device as already described.

(187) In FIG. 38, when the contact on the right between blade 71 and conductive part 17 is closed and locked by the magnetic lock 11, the contact on the left is open.

(188) Since the permanent magnet of the contact on the right is much closer to the ferromagnetic part 15 compared to that of the contact on the left with its part 15 on the left facing, the magnetic attraction force is very much greater on the right side and the reversing switch device 70 remains locked in this position.

(189) To make the pivoting rigid blade 71 switch over and therefore achieve the reversal, the method is as follows.

(190) A BMS commands the injection of a current into the coil 21 on the right, such that the magnetic field generated by the coil opposes that of the permanent magnet 12 on the right.

(191) The force maintaining the contact on the right decreases strongly and is canceled out at the end of a certain time.

(192) At one moment, the attraction torque, defined as being the product between the attraction force and the length of one of the parts of the blade, exerted by the permanent magnet 12 on the left, becomes greater than the torque maintaining the contact on the right and the blade 71 then switches over, opening the contact on the right and closing the contact on the left.

(193) The BMS can possibly command the injection of a current into the coil of the contact on the left to transiently increase the magnetic field generated by the permanent magnet on the left. That makes it possible to manage the speed of switchover of the rigid blade 71.

(194) When the rigid blade 71 has switched over, the magnetic lock 11 on the left keeps the contact on the left locked in this new position and the powering of the control coils 21 can be cut.

(195) A reverse operation of the device 70 is of course possible to revert to the initial state.

(196) Instead of arranging the magnetic locks 11 in the bottom fixed part of the reversing switch device 70, they can be located in the rigid blade 71.

(197) FIGS. 39A to 39E show the different phases of a device 80 both for connection/disconnection between an accumulator A and busbars B1, B2, and for shunt of this accumulator A disconnected because it has failed.

(198) Here, a magnetic lock 11.1 is incorporated in each of the output terminals 4, 5, of the accumulator.

(199) Each lock 11.1 of a terminal 4, 5 comprises a conductive cavity 17 within which is housed a ferromagnetic part 14 which itself houses a permanent magnet 12.1 and a coil 21 around the magnet 12.1.

(200) Two ferromagnetic parts 15 are each inserted into one of the two busbars B1, B2, forming closure plates of a magnetic circuit with the magnetic lock 11 of one or other of the output terminals 4, 5.

(201) Two flexible electrically conductive blades 81 are each fixed at one of its ends to a fixing point 82. Each blade 81 comprises a cavity within which is housed only a permanent magnet 12.2 forming a magnetic lock 11.2.

(202) As can be seen in these FIGS. 39A to 39E and as explained hereinbelow, a permanent magnet 12.2 of a flexible blade 81 is facing a permanent magnet 12.1 of a magnetic lock 11.1 of a terminal 4, 5, with their poles of the same sign, positive in the example illustrated, facing one another.

(203) The operation of a connection/disconnection and magnetic shunt device 80 is as follows.

(204) When the BMS 30, incorporated in the accumulator housing, detects a normal operation of the accumulator, the magnetic attraction force of the permanent magnets 12.1 of the output terminals 4, 5 respectively on the facing closure plates 15, in the closed magnetic circuit configuration, ensures the mechanical connection between said output terminals 4, 5 and the busbars B1 and/or B2 with electrical contact between them (FIG. 39A).

(205) In this configuration, the permanent magnets 12.2 of the flexible blades 81 are repulsed by the permanent magnets such that the flexible blades 81 cannot be in electrical contact with the busbars B1, B2, that is to say away from them (FIG. 39A).

(206) When the BMS 30 detects a failure of the accumulator A, it powers, from the voltage and the energy of the accumulator, the coils 21 of the output terminals 4, 5, through electrical power supply wires incorporated in the accumulator A (FIG. 39B).

(207) The failure of the accumulator can be detected from at least one of the following parameters: the skin temperature, the internal temperature, the voltage and the resistance of the cell.

(208) The powering of the coils 21 is done in a direction such that they each generate a magnetic force opposite to the magnetic attraction force of the permanent magnets 12.1 of the terminals 4, 5 until the mechanical and electrical disconnection between output terminals 4, 5 and, respectively, the two busbars B1, B2 is ensured (FIG. 39C).

(209) This disconnection causes the accumulator to drop through gravity.

(210) For the powering of the coils 21, advantageously, the current is made to increase from 0 to a predefined value with a ramp that is sufficiently slow, 1 to 2 s for example, to allow time for the accumulator to fall through gravity, when the resulting magnetic field, that is to say that resulting from the permanent magnets 12.1 and the coils 21, becomes insufficient to compensate for the weight of the accumulator.

(211) The magnetic fields generated by the coils 21 can continue to increase a little when the accumulator has dropped, and that is inconsequential. The current is cut after a fixed time, 2 s for example.

(212) Simultaneously or quasi-simultaneously with the dropping of the accumulator, because of the absence of magnetic repulsion, the magnetic circuit is closed between the permanent magnets 12.2 of the flexible blades 81 and the closure plates 15 and the electrical connection is made between the busbars B1 and B2 through the flexible blades 81 (FIG. 39D).

(213) In other words, the mechanical and electrical disconnection between output terminals 4, 5 and busbars B1 and B2 is accompanied simultaneously by the electrical connection to the busbars B1 and B2 by the conductive flexible blades 81. This electrical connection to the busbars B1 and B2 constitutes a shunt of the accumulator A while reestablishing the electrical continuity in place of the accumulator A.

(214) To finalize the operation of the device, the dropping of the accumulator A can be done guided in a recess containing a heat-transfer liquid L (FIG. 39E). Thus, the accumulator A embedded in the heat-transfer liquid L is made inert. The heat-transfer liquid can be that of a cooling circuit of a battery pack in which the accumulator is incorporated or a liquid independent of said cooling circuit brought into the recess under the control of the BMS or a liquid resulting from the change of state of a phase change material (PCM) obtained by heating up the accumulator.

(215) Depending on the voltage and current of the accumulator, in case of risk of electrical arc when the accumulator drops through gravity provoking its mechanical and electrical disconnection, it is possible to implement the means previously described with reference to FIGS. 28A to 33B.

(216) Instead of a coil 21, it is possible to arrange in each output terminal 4, 5 an electrical heating resistor. The power supply of this heating resistor is designed to heat up the permanent magnets 12.1 to a temperature higher than their Curie temperature. The permanent magnets 12.1 are then demagnetized, and definitively so.

(217) The advantage over the coils 21 is that the definitively demagnetized permanent magnets cannot prevent magnetic locking of the flexible blades 81, even if the accumulator disconnected for any reason remains close to the closure plates 15. Here, in case of significant heating of the failing accumulator, for example following a thermal runaway, the demagnetization of the permanent magnets 12.1 can be obtained by the heating itself without requiring electronic control or BMS.

(218) Whether the disconnection is provoked by a coil 21 or an electrical heating resistor, a failing accumulator exhibits a voltage and a capacity that are minimal for the electrical power supply. This minimal energy is therefore advantageously exploited for the disconnection of the faulty accumulator.

(219) Typically, as an indication, a magnetic lock commonly used for closing gates with a contact force of 300 daN requires, for its unlocking, a pulse of 12V/550 mA for a few seconds.

(220) In the case of an Li-ion accumulator, this unlocking energy for a 3V accumulator corresponds to a current of 2 A for a few seconds that the failing accumulator can supply without difficulty.

(221) In place of the BMS 30 specific to the failing accumulator, it is possible to use other electronic monitoring systems which will control the electrical powering of the coils 21 or electrical heating resistors. It may be a general BMS of a battery pack or of a non-failing accumulator which will be dedicated to that within a battery pack.

(222) FIGS. 40 and 41 illustrate a concrete exemplary embodiment of a magnetic connection/disconnection and shunt device 80 which has just been described: the blades or tongues 81, of the type made of copper-beryllium, are fixed by a rivet 82 to an insulating substrate 16 into which the busbars B1 and/or B2 are inserted.

(223) FIGS. 42A and 42B illustrate a variant of passive detection of a magnetic disconnection of an accumulator A from the busbars B1 and/or B2. Here, the fixed part of the connection/disconnection device 10 incorporates a relay switch 90, commonly called reed switch.

(224) This reed switch 90 is facing a permanent detection magnet 91 arranged in the accumulator.

(225) More specifically, the permanent detection magnet 91 facing the reed switch 90 closes the latter when the accumulator A is connected to the busbars B1 and/or B2 (FIG. 42A).

(226) When the accumulator A is disconnected, the permanent magnet 91 is too far away to close the switch 90 which therefore opens (FIG. 42B). This opening provokes an opening of the circuit formed with a BMS 30 and the electrical links 33, 34. Thus, completely passively, the BMS 30 can detect the fact that the accumulator A is disconnected from the busbars B1, B2. The detection magnet 91 can be a dedicated magnet or else the permanent magnet of the magnetic lock of the accumulator.

(227) FIG. 43 shows an advantageous implementation of a reversing switch 70 illustrated in FIG. 38. In this implementation, the magnetic disconnection of an accumulator A with shunt can be done by just one of its terminals 5.

(228) In the example illustrated in FIG. 43, the accumulator A is of cylindrical geometry and comprises an output terminal 5 on one side of the packaging 6, for example the cover 9, and the other output terminal 4 is on the other of the sides of the packaging 6, for example on the bottom 8.

(229) In this example of FIG. 43, the accumulator is arranged vertically. However, it is also perfectly possible to envisage arranging it horizontally.

(230) Here, the output terminal 5 on the top is electrically connected to the busbar B1 by one of the magnetic locks 11 of the reversing switch 70 (on the left in FIG. 39). This connection ensures the mechanical strength of the accumulator A.

(231) The other output terminal 4 is electrically connected to the busbar B2 by an electrically conductive wire or foil 74, typically made of copper, which can advantageously be surrounded by an electrically insulating sheath, not represented.

(232) Just like that represented in FIG. 38, the reversing switch 70 comprises a rigid blade 71 articulated at its center by an articulation 72. The current is also brought to this blade 71 by a metal braid 73, preferably made of copper electrically spot welded to improve this electrical link.

(233) The rigid blade 71 incorporates, at each of its ends, if necessary in a conductive part 17, a magnetic lock 11 with permanent magnet 12 provided with a coil 21.

(234) Ferromagnetic parts 15 each intended to close a magnetic circuit with one of the magnetic locks 11 is arranged on the busbars B1 and B2 and in the output terminal 5.

(235) In connection configuration, the contact on the left between blade 71 and the output terminal 5 is closed and locked by the magnetic lock 11, the contact on the right is open.

(236) Since the permanent magnet of the contact on the left is much closer to the ferromagnetic part 5 compared to that of the contact on the right with its part 15 on the right facing, the magnetic attraction force is very much greater on the left side and the reversing switch device 70 remains locked in this position.

(237) To make the pivoting rigid blade 70 switch over and therefore achieve the disconnection of the accumulator with production of the shunt by reversal, the method is as follows.

(238) A BMS commands the injection of a current into the coil 21 on the left such that the magnetic field generated by the coil opposes that of the permanent magnet 12 on the left.

(239) When the magnetic lock 11 on the left opens, only the output terminal 5 is magnetically disconnected and the accumulator drops through gravity.

(240) Simultaneously, the rigid blade 71 has switched over, the magnetic lock 11 on the right keeps the contact on the right locked in this new position (FIG. 43) and the powering of the control coil 21 can be cut.

(241) Thus, in this embodiment, the mechanical and electrical disconnection of the accumulator A is produced only on one of the output terminals, which causes the latter to drop through gravity. The simultaneous reversal produced on the busbar B2 by the reversing switch 70 constitutes a shunt of the accumulator A while reestablishing the electrical continuity in place of the accumulator A.

(242) Here again, instead of arranging the magnetic locks 11 in the rigid blade 71, of the reversing switch device 70, they can be located in the busbars B1 and B2.

(243) It goes without saying that a sufficient length of the foil or wire 74 is provided so as not to hamper the accumulator A when it drops.

(244) With all of the magnetic connection/disconnection devices 10, 60, and, if appropriate, the magnetic shunt device 80 with, if appropriate, a reversing switch device 70, which have just been described, following a failure of an accumulator or the need for a modification of the electrical architecture of a battery pack, it is possible to implement an electrical and/or mechanical disconnection of an accumulator, reconfigure an electrical architecture of a battery pack, if necessary by producing a shunt of one or more accumulators of the pack.

(245) Some embodiments allow a deactivation of the permanent magnet or magnets with no BMS intervention, that is to say completely passive embodiments. These embodiments can advantageously be implemented if a maximum safety is desired for the operation of an individual accumulator or of a battery pack.

(246) In other words, with all of the magnetic connection/disconnection devices 10, 60, and, if appropriate, the magnetic shunt device 80 with, if appropriate, a reversing switch device 70, it is possible to envisage producing different battery pack P architectures, for the purposes of active control on demand and/or for the purposes of safety with continuity of operation of the pack.

(247) FIGS. 44 to 46 show the production, by means of magnetic connection/disconnection devices 10, of a battery pack P1 comprising the parallel connection of a plurality of accumulators A1, . . . Ax by busbars B1, B2 to form a branch M1 linked electrically in series through busbars B3 with other similar branches M2, M3.

(248) For each branch M1, M2, M3, a connection assembly 100 comprising an electrically insulating substrate 16 in which busbars B1, B2 are inserted is produced (FIG. 44).

(249) After having housed the plurality of the accumulators A1 . . . Ax of each branch in recesses 102 of a honeycomb structure 101, the connection assembly 100 is fixed by the plurality of magnetic connection/disconnection devices 10 (FIG. 45).

(250) Then, the series connection of the branches M1, M2, M3 is produced by means of busbars B3.

(251) If only the unit disconnection of failing accumulators is wanted, each accumulator A1, . . . Ax of each branch M1, M2, M3 here comprises a BMS 30 which is specific to it.

(252) In the case where an active control of such a battery pack P1 is wanted, for example to increase the power of the pack P1 on demand, it is possible to cut or temporarily power a branch by means of one or more magnetic connection/disconnection devices with shunt 60 and/or one or more reversing switches 70. In this case, preferably, each branch M1, M2, M3 comprises a single BMS which can command the injection of an electrical current into the magnetic locks 11.

(253) A battery pack P1 with two magnetic connection/disconnection devices with shunt 60.1, 60.2 is thus shown in FIGS. 47 and 48.

(254) In full-power operation of the pack P1, one of the devices 60.1 (the outermost of the pack in FIGS. 47 and 48) is not activated and the other of the devices 60.2 (the innermost of the pack in FIGS. 47 and 48) acts as a serial link busbar B3 between two branches M1, M2 (FIG. 47). The set of the branches is then connected. The direction of the current is indicated in FIG. 47.

(255) In case of need or desire for lower-power operation of the pack P1, the overall BMS of the pack P1 activates the device 60.1 which is inactive in full-power mode and opens the device 60.2 which is active in full-power mode (FIG. 48). The branch M1 is then shunted to provide less power.

(256) If wanting to further improve the dependability of the pack upon the switchover from full power to lower power, it is possible to implement, instead of the two devices 60.1, 60.2, a single reversing switch 70 which, in one of its switchover positions, produces the electrical connection between the busbars B1 and B2 to connect all of the branches M1, M2, etc. and, in the other of its switchover positions, produces the shunt of one of the branches M1, M2 etc.

(257) This embodiment is illustrated in FIGS. 49 and 50. In full-power operation illustrated in FIG. 49, the connection in electrical series between two branches M1-M2, M2-M3 is ensured by a reversing switch 70.1, 70.2, 70.3 described and illustrated with reference to FIG. 43. Thus, the metal braid 73.1, 73.2, 73.3 ensures the electrical link between the busbar B2 of the preceding branch to the busbar B1 of the next one. In case of necessity, particularly in case of failure of the branch M2, or of desire for the pack P1 to operate at lower power, the overall BMS of the pack P1 activates the reversing switch 70.2 such that its rigid blade pivots (FIG. 46). The branch M2 is then shunted and the pack P1 can operate with the power of the other branches M1 and M3 still connected in series.

(258) FIGS. 51 to 53 show the production, by means of magnetic connection/disconnection devices 60, of a battery pack P2 comprising the parallel connection of a plurality of accumulators A1, . . . Ax by busbars B1, B2 to form a branch M1 linked electrically in series through busbars B3 with other similar branches M2, M3.

(259) In this architecture, a failure of an accumulator A1 can have a high impact on its accumulator in parallel A2, . . . Ax. Indeed, the loss of capacity of the failing accumulator A1 will not be compensated by the adjacent accumulator A2.

(260) It is therefore necessary to shunt the branch M1, M2 or M3 of the failing accumulator in order to ensure the electrical performance levels of the battery pack P2 and ensure a continuity of operation or of service of P2.

(261) The actuation of a device 60 at the end of the branch, containing the failing accumulator, produces the desired magnetic shunt and therefore the continuity of operation of P2.

(262) FIGS. 55 to 57 show the production, by means of magnetic connection/disconnection devices with shunt 80, of a battery pack P3 comprising the series connection of a plurality of accumulators A1, . . . Ax by busbars B1, B2 to form a branch M1 linked electrically in parallel through busbars B3 with other similar branches M2, M3.

(263) In this battery pack P3 architecture, each accumulator A1, . . . Ax of each branch M1, M2, M3 comprises a BMS 30 which is specific to it.

(264) In this architecture, a failure of a given accumulator can have a great impact on all of the pack P3. Indeed, the loss of an accumulator in series can cause a reduction of the voltage of the branch which contains the failing accumulator, with, ultimately, an imbalance between the branches. An imbalance can lead to an overvoltage internal to the pack P3, which can cause the general runaway thereof.

(265) In this architecture, it is important to consider the chemistry of the accumulators, which must be capable of withstanding an overvoltage. For example, in the case of an Li-ion accumulator, the lithium iron phosphate LFP has a so-called “flat” discharge curve, which makes it possible to have a uniform range during charging or discharging. Also at least twice the nominal voltage has to be reached in order to perceive a start of runaway, which makes it possible to absorb a voltage difference between the two branches and to rebalance all of the system.

(266) Each failing accumulator can be disconnected then shunted by means of a device 80.

(267) Thus, the safety and the continuity of service of the battery pack P3 are constantly ensured whatever the failing accumulator by means of the devices 80 individually dedicated to each accumulator of the pack P3.

(268) By virtue of the magnetic connection/disconnection devices, if appropriate with magnetic shunt which have just been described, an assembly time and a production cost of a battery pack are obtained that are truly reduced compared to the methods of assembling accumulators according to the state of the art by one or more busbars by welding, screwing or any other methods.

(269) The steps of assembly of a battery pack P3, of which some of the components are illustrated in FIGS. 58 and 59, can be as follows.

(270) Step a/: a connection assembly 100 incorporating busbars B1, B2 is positioned in an electrically insulating substrate 16 upside down, with the flexible blades 81 ensuring the continuities of service positioned under the substrate 16. Given the magnetic forces involved, the blades 81 are in closed position, that is to say magnetically locked on the busbars B1, B2.

(271) Step b/: a honeycomb structure 101 made of electrically insulating material, comprising recesses in the form of cells 102 suitable for each housing an accumulator, is fixed by snapfitting onto the connection assembly 100.

(272) Step c/: the accumulators A1, . . . Ax are inserted into the cells 102, each of a form suitable for producing a guiding of an accumulator of complementary form. At this stage, each accumulator is in magnetic levitation above the busbars B1, B2 by virtue of the passive repulsion between permanent magnets 12.1, 12.2 of the magnetic locks 11.1, 11.2 of the devices 80.

(273) Step d/: there is then applied in succession, below each accumulator, a magnetic field that can be varied to cancel the field in the lock 11.2 of the shunt. The latter will open under the effect of the spring of the flexible blade 81 and the accumulator will lower into position. The decreasing of the mounting magnetic field under the accumulator will allow it to be connected with locking onto the busbars B1, B2 through the magnetic locks 11.1. The control of the magnetic field makes it possible to obtain a soft and gradual connection. The forces involved in the magnetic locks 11.1 are sufficient to support the weight of the accumulators and have a low contact resistance.

(274) Step e/: The battery pack P3 thus formed is then closed by a base 103 including the battery-pack cooling system.

(275) In addition to the reduced assembly time and cost, the method with the steps described has the important advantage of not handling the bare live parts which usually require restrictive accreditations (of TST type).

(276) The invention is not limited to the examples which have just been described; it is in particular possible to combine with one another the features of the examples illustrated within variants that are not illustrated.

(277) Other variants and enhancements can be envisaged without in any way departing from the scope of the invention.

(278) Generally, the magnetic locks 11 according to the invention can be arranged either in the fixed parts, or in the mobile parts of the assembly of the magnetic connection/disconnection devices with shunt and reversing switches illustrated.

(279) More specifically, except for the configurations in which the shunt of an accumulator is sought, it is possible to envisage incorporating a magnetic lock, either in an output terminal of an accumulator, or alongside a busbar, and respectively the magnetic closure plate cooperating with the magnetic lock, either on the side of the busbar, or in the output terminal of an accumulator.

(280) In the context of the invention, any coil can be powered by any of the accumulators of a battery pack. According to an advantageous variant, when it is incorporated in an output terminal of an accumulator, it can be powered directly thereby.

(281) Regarding the advantageous mounting of a battery pack according to the invention, initially prior to their mechanical and electrical connection with locking, the accumulators are each in magnetic levitation to avoid the undesirable contact which would be due to a magnetic force opposing the weight of the accumulator. The applied magnetic field which allows this levitation must be variable to be able to manage a gradual approach between the accumulator and the busbar to which it must be connected mechanically and electrically and locked.

(282) It is possible to envisage several ways of applying this variable magnetic field: through external tooling provided with a permanent magnet whose magnetic field is then made to vary either by moving it away from the accumulator, or by using an external coil, or by using the coil of the lock incorporated in one of the terminals of the accumulator; through blades on the side of the busbar, which then incorporate a magnetic lock comprising a permanent magnet and a coil whose magnetic field is then made to vary.

(283) While, throughout the examples illustrated, the packagings of the accumulators according to the invention are rigid packagings (housings), the invention applies obviously to all the accumulators with flexible packaging in which a magnetic lock or a corresponding magnetic closure plate can be incorporated.

(284) While, throughout the examples illustrated, the housings of the accumulators according to the invention are electrically conductive, the invention applies obviously to all the accumulators with electrically insulating housings.

(285) Furthermore, while, throughout the examples illustrated, the output terminals of the accumulators according to the invention have a generally cylindrical form, the invention applies obviously to all the geometrical forms of terminals (square or rectangular, hexagonal, or other section).

LIST OF REFERENCES CITED

(286) [1] Xuning Fenga, et al. “Key Characteristics for Thermal Runaway of Li-ion Batteries” Energy Procedia, 158 (2019) 4684-4689. [2] M. Soka et al. «Role of thermomagnetic curves at preparation of Ni Zn ferrites with Fe ions deficiency», Journal of Electrical Engineering, Vol. 61 No. 7/s, 2010, pp 163-165. [3] K Murakami «The characteristics of Ferrite cores with low Curie temperature and their application», IEEE Transactions on magnetics, Volume: 1, Issue: 2, June 1965.