LOCAL ANALOGUE EQUILIBRATING SYSTEM FOR A SET OF DEVICES FOR STORING ELECTRICAL POWER VIA A CAPACITIVE EFFECT, ELECTRICAL INSTALLATION, TRANSPORT VEHICLE AND RECHARGEABLE STORAGE MODULE COMPRISING SUCH A SYSTEM

Information

  • Patent Application
  • 20190267816
  • Publication Number
    20190267816
  • Date Filed
    November 15, 2017
    7 years ago
  • Date Published
    August 29, 2019
    5 years ago
Abstract
An analogue system for balancing an electrical energy storage assembly having a plurality of capacitive effect electrical energy storage devices connected to one another in series, the system including, for each storage device, a balancing device including: a bypass circuit for the storage device, able to be controlled between a closed state and an open state;a first voltage comparator for controlling an open or closed state of the bypass circuit depending on a balancing voltage; anda second voltage comparator for controlling an open or closed state of the bypass circuit depending on a switch-off voltage.
Description

The present invention relates to an analogue balancing system for an assembly of capacitive-effect storage devices connected to one another in series. It also relates to a rechargeable electrical energy storage module, an electric or hybrid transport vehicle and a power supply installation implementing such a system.


The field of the invention is the field of systems for balancing supercapacitors that are connected in series.


BACKGROUND

A supercapacitor stores electrical energy through a capacitive effect. The main limitation of a supercapacitor is that it operates only at a very low voltage. To achieve the desired operating voltage, the supercapacitors are placed in series in a rechargeable electrical energy storage module.


However, on account of manufacturing differences or differences in ageing, the supercapacitors of one and the same storage module only rarely charge at the same rate. In order to ensure a greater homogeneity in the voltage across the terminals of the supercapacitors in series, a balancing system is provided, in analogue form for reasons of cost, reliability, feasibility and robustness.


This analogue balancing system enables, during a charging phase, diversion of at least some of the current for each supercapacitor, on an individual basis, when the voltage across its terminals exceeds a predetermined voltage, called balancing voltage. At the end of the charging phase, if the balancing voltage is exceeded for all of the supercapacitors, this generally being the case, all of the supercapacitors are therefore bypassed.


Thus, when the charging phase is not followed immediately by a discharging phase, but by an under voltage phase or by a rest phase, each supercapacitor remains bypassed and discharges into the bypass circuit for as long as the voltage across its terminals is greater than the balancing voltage. In other words, during an under voltage phase or a rest phase separating a charging phase from a discharging phase, the supercapacitors discharge into the bypass circuit while they are not being used. A loss of energy therefore occurs, which is compensated in the case of an under voltage phase, and not compensated in the case of a rest phase, this being costly in any case and reducing the efficiency and autonomy of the supercapacitors, and therefore of the storage module.


A purpose of the present invention is to overcome these drawbacks.


Another purpose of the invention is to propose a more efficient balancing system for an assembly of capacitive-effect storage devices connected to one another in series.


It is also a purpose of the invention to propose a balancing system for an assembly of capacitive-effect storage devices in series that makes it possible to reduce, or even eliminate, energy losses and to improve the efficiency and the autonomy of said assembly.


SUMMARY OF THE INVENTION

The invention makes it possible to achieve at least one of these aims with an analogue system for balancing a rechargeable electrical energy storage assembly comprising a plurality of capacitive-effect storage devices connected to one another in series, said system comprising, for each storage device, a balancing device including:

    • a bypass circuit for said storage device, able to be controlled between a closed state and an open state, and
    • a voltage comparator, celled first comparator, arranged to control said bypass circuit into an open or closed state, depending on the voltage on the terminals of said storage device
    • and on a predetermined voltage, called balancing voltage, denoted Veq hereinafter;


      said system being characterized in that it further comprises, for each storage device, another voltage comparator, celled second comparator, arranged to control an open or closed state of the bypass circuit for said storage device depending on:
    • the voltage on the terminals of said storage device and
    • a predetermined voltage, called switch-off voltage, representative of a closed state of the majority, or of all, of the bypass circuits, and denoted Vdec hereinafter.


In particular, Vdec>Veq.


Thus, the system according to the invention provides to switch off, i.e. for to open, the bypass circuit for each storage device when the majority or the entirety of the bypass circuits are in a switched-on state, i.e. a closed state. Thus, the system according to the invention makes it possible to prevent the storage devices from remaining bypassed, by current diversion circuits, after a charging phase. The system according to the invention hence makes it possible to prevent the storage devices from discharging into the bypass circuits, and in particular into bypass resistors of said bypass circuits, between a charging phase and a discharging phase.


As a result, the system according to the invention makes it possible to achieve more efficient balancing, to reduce energy losses and to improve the efficiency and autonomy of the storage assembly.


In addition, control of the bypass circuit for each storage device is performed individually by a second comparator that is dedicated to said storage device. As a result, the system according to the invention has great flexibility, but also increased robustness. Specifically, a malfunction in a second comparator associated with one storage device will not have any effect on the balancing of another storage device.


In the present application, “capacitive-effect storage device”, also called “storage device”, is understood to mean a device comprising, or formed of, one or more supercapacitors connected to one another in series or in parallel.


In the majority of cases, but without limitation, the capacitive-effect storage devices each comprise a single supercapacitor and have one and the same balancing voltage and one and the same switch-off voltage.


According to one configuration, the first comparator directly receives the voltage Vi on the terminals of the storage device. In this case, the first comparator directly compares the voltage Vi with the balancing voltage Veq.


Alternatively, a first voltage divider may be used to adjust the voltage Vi at the input of the first comparator. The first comparator then receives an input voltage ViE1, such that ViE1=Vi/Di1, where Di1 is the coefficient of division applied by the first voltage divider. In this case, the first comparator compares the voltage ViE1 with a first voltage, called first reference voltage, denoted Vref1 and chosen such that Vref1=Veq/Di1.


According to one configuration, the second comparator directly receives the voltage Vi on the terminals of the storage device. In this case, it directly compares the voltage Vi with the switch-off voltage Vdec.


Alternatively, a second voltage divider may be used to adjust the voltage Vi at the input of the second comparator. The second comparator then receives an input voltage ViE2 such that ViE2=Vi/Di2, where Di2 is the coefficient of division applied by the second voltage divider. In this case, the second comparator compares the voltage ViE2 with a second voltage, called second reference voltage, denoted Vref2 and chosen such that Vref2=Vdec/Di2.


In one particularly advantageous configuration, the first and second voltage dividers may be dimensioned such that:






V
ref1
=V
ref2
=V
ref.





In this case, we have:






V
dec
/D
i
2
=V
eq
/D
i
1,






V
dec
/V
eq
=D
i
2
/D
i
1.


According to one non limiting exemplary implementation, each voltage divider may be formed by resistor bridges.


Moreover, considering that the capacitors of each storage device to be balanced are of between a minimum value Cmin and a maximum value Cmax, Vdec may be taken such that:








V
dec


V
eq


=


C
max


C
min






More generally, it is possible to set a standard range of variation for the capacitors [C=C (1±ΔC), where ΔC<<1, typically ΔC≤10%] and to set Vdec such that:







V
dec

=




1
+

Δ





C



1
-

Δ





C





V
eq





(

1
+

2





Δ





C


)







V
eq







Moreover, Vdec must be lower than the maximum operating voltage, denoted Vmax, of the storage device, in particular provided by the application.


According to one particularly advantageous feature, for at least one, in particular each, storage device, at least one of the first and second comparators may be referenced to the potentials on the terminals of said storage device, and be configured to supply, as output:

    • in a first state: the smallest potential, denoted Vi, on the terminals of said storage device; and
    • in a second state: the greatest potential, denoted Vi+, on the terminals of said storage device.


The comparator(s) thus adjust(s) to the variation, over time, in the voltage across the terminals of the storage device, thereby making it possible to achieve a more efficient and more precise balancing.


In addition, it is not necessary to provide an additional voltage source for referencing the comparator(s), thereby reducing the cost and the bulk of the system according to the invention.


Finally, the comparator(s) operate(s) in a voltage range that does not exceed the maximum voltage across the terminals of each storage device, thereby enabling the use of less expensive and less bulky components in comparison with components operating at a very high voltage.


Advantageously, the system according to the invention may comprise, for at least one, in particular each, storage device:

    • a voltage divider, called first voltage divider, supplying, to the first comparator, a first input voltage that is proportional to and lower than said voltage on the terminals of said storage device; and/or
    • a voltage divider, called second voltage divider, supplying, to the second comparator, a second input voltage that is proportional to and lower than said voltage on the terminals of said storage device.


A voltage divider makes it possible to adjust, in particular to reduce, the voltage across the terminals of the storage device, so as to use a commercially available voltage source for the comparison performed by the first comparator, respectively the second comparator.


Indeed, from a practical point of view, the analogue electronic voltage sources have determined and set values. They therefore do not necessarily correspond to the value of the desired balancing voltage Veq, respectively to the value of the desired switch-off voltage Vdec.


Advantageously, for at least one storage device, the voltage divider(s) may be dimensioned such that the first and second comparators perform a comparison of the input voltages at one and the same reference voltage, in particular supplied by one and the same single source.


The cost and bulk of the balancing system are thus reduced.


In this case, the voltage divider(s) may be chosen such that:






V
dec
/V
eq
=D
i
2
/D
i
1


where Di1 and Di2 are the coefficient applied by the first voltage divider and by the second voltage divider, respectively.


In all of the applications, Vdec>Veq. Thus, in one particular embodiment, only the second voltage divider may be used, with a coefficient Di2 such that:






V
dec
/V
eq
=D
i
2


In addition, at least one, and in particular each, of the first and second comparators may be a hysteresis comparator.


Such a hysteresis comparator makes it possible to prevent erratic changes of state by the control signal supplied by said comparator.


In a first exemplary implementation, at least one, in particular each, bypass circuit may comprise two switches, in series in said bypass circuit, one controlled depending on the voltage supplied by the first comparator and the other controlled depending on the voltage supplied by the second comparator.


Alternatively, or in addition, at least one, in particular each, bypass circuit may comprise a single switch, the balancing device furthermore comprising a means for controlling said single switch depending on the voltages supplied by the first and second comparators.


The cost, power consumption and bulk of the system according to the invention are thus reduced.


According to a exemplary implementation, for at least one, in particular each, balancing device, the means for controlling the single switch may comprise:

    • a transistor that is in the off, or blocked, state by default, for example an NPN bipolar transistor, in particular when the second comparator is an inverting comparator, or
    • a transistor that is in the on state by default, for example a PNP bipolar transistor, in particular when the second comparator is a non-inverting comparator.


In the case where a bipolar transistor is used, the base of said bipolar transistor is connected to the second comparator, the collector to the first comparator and the emitter to the single switch.


In this case, the voltage of the emitter of the transistor, denoted Vic, may be used to control the single switch associated with the storage device.


According to one particularly advantageous feature, the system according to the invention may furthermore comprise a device for monitoring the operation of said balancing system, and possibly signal an operating fault in said system.


According to a first embodiment, the monitoring device may perform monitoring of the operation of said balancing system depending on the voltages supplied by the second comparators.


Such a device may be designed to take a weighted sum of all of the voltages supplied by the second comparators of all of the storage devices and compare the weighted sum obtained with a first threshold voltage, using a voltage comparator for example.


This first threshold voltage may be the voltage V across the terminals of the storage assembly, that is to say V=Vn+−V1.


It is also possible to take into account, in the first threshold voltage, a voltage δV representing a safety margin. In this case, the threshold voltage may be equal to: V−δV.


Alternatively, the voltage δV representing a safety margin may be added to the weighted sum.


According to a second embodiment, and when the bypass circuit of each balancing device comprises a single switch controlled by a control means, the monitoring device may perform monitoring of the operation of said balancing system depending on the control voltages of said single switches of all of the balancing devices.


Such a device may be designed to take a weighted sum of all of the control voltages and compare the sum obtained with a second threshold voltage, using a voltage comparator for example.


This second threshold voltage may be the voltage V across the terminals of the storage assembly, that is to say V=Vn+−V1.


It is also possible to take into account, in the second threshold voltage, a voltage δV representing a safety margin. In this case, the threshold voltage may be equal to: V−δV.


Alternatively, the voltage δV representing a safety margin may be added to the weighted sum.


According to a third embodiment, and when the bypass circuit for each balancing device comprises a single switch controlled by a means for controlling said single switch, the device for monitoring the operation of said system may perform monitoring depending on:

    • the control voltage of said single switch, and
    • the voltage supplied by the first comparator;
    • of each balancing device.


In particular, in one non limiting exemplary implementation of this third embodiment, the monitoring device may comprise, for each balancing device:

    • a controllable switch, called third switch, and
    • a comparator, called third comparator, for controlling said third switch.


All of the third switches may be connected to one another in series between two different electrical potentials, such as for example the potentials V1 and Vn+ on the terminals of the storage assembly.


Each third comparator, associated with a balancing device, performs a comparison of:

    • the control voltage of the single switch of the balancing device, and
    • the voltage supplied by the first comparator of said balancing device; for controlling the third switch that is associated therewith, depending on said comparison.


Each pair (third switch+third comparator) associated with a balancing device may be configured such that the third switch is controlled into a closed state when the single switch of said balancing device changes to a closed state.


In particular:

    • each 3rd comparator may be an inverting comparator, or respectively a non-inverting comparator; and
    • each 3rd switch may be a transistor that is in the off, or the blocked, state by default, for example an NPN bipolar transistor, or respectively a transistor that is in the on state by default, for example a PNP bipolar transistor.


According to another aspect of the same invention, a rechargeable electrical energy storage module is proposed, comprising:

    • at least one rechargeable electrical energy storage assembly, each comprising a plurality of capacitive-effect electrical energy storage devices connected to one another in series within said assembly, and
    • for at least one, in particular each, storage assembly, a balancing system according to the invention.


The energy storage module may comprise a plurality of storage assemblies.


At least two, in particular all, of the assemblies may be arranged in series with one another. Alternatively, or in addition, at least two, in particular all, of the assemblies may be arranged in parallel with one another.


At least two, in particular all, of the assemblies may comprise an identical number, or a different number, of storage devices.


According to another aspect of the present invention, a hybrid or electric transport vehicle is proposed, comprising one or more rechargeable electrical energy storage module(s) according to the invention.


“Transport vehicle” is understood to mean any type of means for transporting people or objects, such as a bus, a car, a tram, a boat, a lorry, a cable car, a lift, a goods lift, a crane, etc.


According to yet another aspect of the same invention, an electrical installation is proposed, comprising one or more rechargeable electrical energy storage module(s) according to the invention.


Such an electrical installation may be an electric charging station for electric or hybrid transport vehicles, or a power supply station for a building, for a complex or for an electric/electronic communication device.


Such an electrical installation may be a station for regulating or smoothing, or else buffer storing, electrical energy, for example supplied by an electricity grid or means for producing electricity. Such a regulating or smoothing station makes it possible to store surplus electrical energy during a period of low consumption, respectively high production, and to deliver the stored electrical energy during a period of high consumption, respectively low production.


The installation according to the invention may advantageously comprise a means for producing electrical energy from a renewable source, such as at least one solar panel and/or at least one wind turbine and/or at least one tidal turbine.


The energy produced by such a means may be used to recharge at least one rechargeable electrical energy storage module.


Alternatively, or in addition, at least one rechargeable electrical energy storage module may be recharged from the mains.





DESCRIPTION OF THE FIGURES AND EMBODIMENTS

Other advantages and features will emerge upon examination of the detailed description of entirely nonlimiting embodiments, and of the appended drawings, in which:



FIGS. 1a and 1b show basic overviews of two exemplary implementations of a balancing system with controlled resistance according to the prior art;



FIG. 2 is a depiction of the basic overview of a first exemplary implementation of a balancing system with controlled resistance according to the invention;



FIG. 3 is a depiction of the basic overview of a second exemplary implementation of a balancing system with controlled resistance according to the invention;



FIG. 4 is a schematic depiction of a nonlimiting exemplary implementation of a module for monitoring the operation of a system according to the invention;



FIG. 5 is a schematic depiction of another nonlimiting exemplary implementation of a module for monitoring the operation of a system according to the invention;



FIG. 6 is a schematic depiction of a nonlimiting exemplary implementation of a storage module according to the invention; and



FIGS. 7a-7d are nonlimiting exemplary implementations of a capacitive-effect electrical energy storage device.





It is readily understood that the embodiments that will be described hereinafter are in no way limiting. It will be possible in particular to imagine variants of the invention comprising only a selection of features described hereinafter, in isolation from the other features described, if this selection of features suffices to afford a technical advantage or to differentiate between the invention and the prior art. This selection comprises at least one preferably functional feature without structural detail, or with only a portion of the structural details if this portion alone suffices to afford a technical advantage or to differentiate between the invention and the prior art.


In the figures, elements common to a plurality of figures retain the same reference.


In the following examples, but in a manner that is in no way limiting for the invention, all of the storage devices DCi are considered to be identical and to have the same balancing voltage Veq. Of course, the invention is not limited to these examples, and it is possible to use storage devices DCi that are different from one another and that do not have the same balancing voltage.



FIGS. 1a and 1b are depictions of the basic circuit diagrams of two examples of a balancing system with controlled resistance according to the prior art.



FIGS. 1a and 1b show a storage assembly 100 comprising n capacitive-effect storage devices DC1, . . . , DCn that are connected to one another in series and are identical. The storage device DC1 is situated on the side of the smallest electrical potential, denoted V1, of the storage assembly 100, and the storage device DCn is situated on the side of the greatest electrical potential, denoted Vn+, of the storage assembly 100. The voltage between the terminals of the storage device DCi is denoted Vi, and the voltage between the terminals of the storage assembly 100 is denoted V.


The system shown in FIGS. 1a and 1b comprises a balancing device with controlled resistance that is associated with each storage device DCi.


Hereinafter, so as not to overload the drawings, only the balancing device 102i, associated with the storage device DCi is shown in FIGS. 1a and 1b. The balancing devices of the other storage devices of the storage assembly 100 are on the same principle as the balancing device 102i, shown in FIGS. 1a and 1b, and are in particular identical to the balancing device 102i in the case where the storage devices DCi have one and the same balancing voltage Veq.


The balancing device 102i comprises a bypass circuit 104i, connected in parallel to the terminals of the storage device DCi and including a switch Qi in series with a balancing resistor Rieq.


The balancing device 102i also comprises a hysteresis comparator 106i, called first comparator, for controlling the state of the switch Qi. The first comparator 106i is formed by an operational amplifier 108i and two resistors R and R′, the values of which resistors set the width of the hysteresis. The resistors R and R′ are chosen so as to be large enough for the current that passes through them to be negligible, typically R>10 kΩ and R′>10 kΩ.


The operational amplifier 108i is referenced to the potentials, Vi+ and Vi, across the terminals of the storage device DCi with which the balancing device 102i is associated.


In the example shown in FIG. 1a, the positive input (+) of the operational amplifier 108i is connected to the greatest potential Vi+ across the terminals of the storage device DCi with which the balancing device 102i is associated. The negative input (−) of the operational amplifier 108i is connected to a voltage source 110i that is itself referenced to the smallest potential Vi across the terminals of the storage device DCi.


In the example shown in FIG. 1a, the voltage source 110i supplies the balancing voltage Veq at which it is desired to bypass the storage device DCi.


In this case, the comparator 106i directly compares the voltage Vi across the terminals of the storage device DCi with the balancing voltage Veq, and operates in the following manner:

    • if Vi (=Vi+−Vi)<Veq, then the voltage supplied by the first comparator 106i denoted Vis, is equal to Vi (=−Vsat local): in other words, if the voltage Vi across the terminals of the storage device DCi is lower than the balancing voltage Veq, then Vis=Vi; and
    • if Vi (=Vi+−Vi)≥Veq, then Vis=Vi+ (=+Vsat local).


The voltage Vis is used to control the switch Qi into a closed state or into an open state.


In the example shown in FIG. 1a, the switch Qi may be an N-channel MOSFET transistor, the gate of which receives the voltage Vis:

    • when Vis has the value Vi (that is, when the voltage Vi across the terminals of the storage device DCi is lower than the balancing voltage Veq), then the gate-source voltage is zero and the switch Qi is in the off state/open: the bypass circuit 104i is open and does not draw any current; and
    • when Vis has the value Vi+ (that is, when the voltage Vi across the terminals of the storage device DCi is greater than or equal to the balancing voltage Veq), then the gate-source voltage is non-zero and the switch Qi is in the on state/closed: the bypass circuit 104i is closed and draws current that flows into the balancing resistor Rieq.



FIG. 1b provides another exemplary implementation of a balancing device with controlled resistance. The balancing device 112i of FIG. 1b comprises a voltage divider 114i arranged as a diversion to the terminals of the storage device DCi and formed by resistors Re and Re′. The voltage divider 114i is used to adjust the voltage Vi (Vi=Vi+−Vi) across the terminals of the storage device DCi. Indeed, from a practical point of view, the analogue electronic voltage sources have determined and set values. They therefore do not necessarily correspond to the value of the desired balancing voltage Veq for the storage device DCi. The comparator 106i thus receives, as input, not the voltage Vi but an input voltage ViE1 such that ViE1=Vi/D1, where D1 is the coefficient of division applied by the voltage divider 114i, such that:







D
1

=



R
e

+

R
e




R
e






In this case, the source 110i supplies not the balancing voltage Veq, but a reference voltage, denoted Vref, such that Vref=Veq/D1.


In other words, we have:








R
e



R
e

+

R
e




=


V
ref


V
eq






In other words, in the exemplary implementation shown, Vref≠Veq, and







V
ref

=


V
eq



(


R
e



R
e

+

R
e




)






The balancing device 112i, shown in FIG. 1b, moreover comprises all of the elements of the balancing device 102i of FIG. 1a.


Unlike the device 102i of FIG. 1a, in the device 112i of FIG. 1b, the positive input (+) of the operational amplifier 108i is connected to said voltage divider 114i. The resistors Re and Re′ forming the voltage divider are chosen so as to be large enough for the current that passes through them to be negligible, typically Re>10 kΩ and Re′>10 kΩ.


In this case, the voltage comparator 106i performs a comparison:

    • of the reference voltage Vref (rather than the voltage Veq)
    • with the input voltage ViE1, supplied by the voltage divider 114i.


In the examples described, the comparator 106i is a hysteresis comparator. Alternatively, the comparator 106i might not be a hysteresis comparator.



FIG. 2 is a depiction of the basic overview of a first non limiting exemplary implementation of a balancing system according to the invention.


The balancing system 200 of FIG. 2 comprises, for each storage device DC1, . . . , DCn, an identical balancing device with controlled resistance, since the storage devices DC1, . . . , DCn are identical.


So as not to overload the drawing, only the balancing device 202i, associated with the storage device DCi, is shown in FIG. 2.


The balancing device 202i comprises a bypass circuit 204i for the storage device DCi comprising the balancing resistor Rieq in series with the switch Qi. The bypass circuit 204i additionally comprises a second switch Qi′, in series with the first switch Qi.


In the same manner as in the balancing device 112i of FIG. 1b, the first switch Qi is controlled by the voltage Vis supplied by the comparator 106i, with the use of the voltage divider 114i.


The switch Qi is a switch positioned in an open state/in the off state as long as the voltage across the terminals of the storage device DCi has not reached the balancing voltage Veq, and is otherwise closed/in the on state.


In the system 200 of FIG. 2, each balancing device 202i furthermore comprises a second switch Qi′ in series with the first switch Qi and the balancing resistor Rieq. The switch Qi′ is chosen and is controlled such that it remains closed/in the on state as long as the voltage Vi across the terminals of the storage device DCi has not reached a predetermined switch-off voltage, denoted Vdec, that is greater than the balancing voltage Veq, and is otherwise open/in the off state.


Each balancing device 202i furthermore comprises a second voltage comparator 206i for controlling the switch Qi′. The comparator 206i is a hysteresis comparator. In particular, the second comparator 206i is formed by an operational amplifier 208i and two resistors R″ and R′″, the values of which resistors set the width of the hysteresis. The resistors R″ and R′″ are chosen so as to be large enough for the current that passes through them to be negligible, typically R″>10 kΩ and R′″>10 kΩ.


The operational amplifier 208i is referenced to the potentials, Vi+ and Vi, across the terminals of the storage device DCi with which the balancing device 202i is associated.


In the example shown in FIG. 2, the positive input (+) of the operational amplifier 208i receives an input voltage, denoted ViE2, that is proportional to the voltage across the terminals of the storage device DCi through a voltage divider 214i formed by resistors Rd and Rd′. The negative input (−) of the operational amplifier 208i is connected to the voltage source 110i, supplying the reference voltage Vref, which is itself referenced to the smallest potential, denoted Vi, across the terminals of the storage device DCi.


As a result, the second voltage divider 214i supplies a voltage ViE2 such that ViE=Vi/D2, where D2 is the coefficient of division applied by the voltage divider 214i, such that:







D
2

=



R
d

+

R
d




R
d






The voltage divider 214i must be dimensioned such that the coefficient D2 satisfies the following relationship:







D
2

=


V
dec


V
ref






In this case, the second voltage comparator 206i performs a comparison:

    • of the reference voltage Vref delivered by the source 110i, with the second input voltage ViE2, supplied by the voltage divider 214i.


Thus, in the exemplary implementation shown in FIG. 2, the reference voltages used by the two comparators 106i and 206i are identical. However, for a given voltage across the terminals of the storage device DCi, the input voltage ViE1 used by the first comparator 106i for the comparison with the reference voltage Vref is greater than that ViE2 used by the second comparator 206i. Thus, the switch-off level Vdec of the switch Qi′ is greater than the switch-on level Veq of the switch Qi.


The second comparator 206 operates in the following manner:

    • if the second input voltage ViE<Vref, this means that Vi<Vdec: in this case the voltage supplied by the second comparator 206i, denoted Vcs, is equal to Vi (=−Vsat local); and
    • if the second input voltage ViE2≥Vref, this means that Vi≥Vdec: in this case the voltage Vcs supplied by the second comparator 206i is equal to Vi+ (=+Vsat local).


In these conditions, the switch Qi′ may be a P-channel MOSFET transistor, the gate of which receives the voltage Vcs:

    • when Vcs has the value Vi, this means that the voltage Vi has not reached the switch-off voltage Vdec, then the gate-source voltage is zero and the switch Qi′ is closed/in the on state: the bypass circuit 204i is closed: the storage device DCi is bypassed depending on the state of the switch Qi; and
    • when Vcs has the value Vi+, this means that the voltage Vi has reached the switch-off voltage Vdec, then the gate-source voltage is positive and, as a result, the switch Qi′ is in the off state/open: the bypass circuit 204i is open regardless of the state of the switch Qi and does not draw current: the storage device DCi is not bypassed.



FIG. 3 is a depiction of the basic overview of a second nonlimiting exemplary implementation of a balancing system according to the invention.


The balancing system 300 of FIG. 3 comprises the first comparator 106i and the second comparator 206i of the system 200 of FIG. 2.


The balancing system 300 furthermore comprises, for each storage device DC1, . . . , DCn, an identical active balancing device with controlled resistance.


So as not to overload the drawing, only the balancing device 302i, associated with the storage device DCi, is shown in FIG. 3.


The balancing device 302i comprises a bypass circuit 304i for the storage device DCi, comprising the balancing resistor Rieq in series with a single switch, namely the switch Qi. In the system 300, the switch Qi is controlled depending both on the voltage Vis supplied by the first comparator 106i and on the voltage Vcs supplied by the second comparator 206i.


To this end, the balancing device 302i comprises a control means receiving, on the one hand, the voltage Vis supplied by the first comparator 106i and, on the other hand, the voltage Vcs supplied by the second comparator 206i. In particular, the control means is a bipolar transistor, denoted Ji, such as a PNP bipolar transistor that is closed/in the on state by default, and connected such that:

    • the base of the transistor Ji receives the voltage Vcs,
    • the collector of the transistor Ji receives the voltage Vis and
    • the emitter of the transistor Ji controls the switch Qi, through a control voltage denoted Vic.


As described above, the switch Qi may be an N-channel MOSFET transistor.


In these conditions, the switch Qi of the bypass circuit 304i is controlled in the following manner:

    • if the voltage Vi across the terminals of the storage device DCi has not reached the balancing voltage Veq, then Vis=Vi and Vcs=Vi. As a result, the bipolar transistor Ji is in the on state/closed and the voltage Vi arrives at the switch Qi, which is then in the off state/open: the bypass circuit 304i does not allow the current to flow;
    • if the voltage Vi across the terminals of the storage device DCi has reached the balancing voltage Veq, but not the switch-off voltage Vdec, then Vis=Vi+ and Vcs=Vi. As a result, the bipolar transistor Ji is in the on state and the voltage Vi+ arrives at the switch Qi, which is then in the on state/closed: the bypass circuit 304i allows the current to flow and the storage device DCi is bypassed; and
    • if the voltage Vi across the terminals of the storage device DCi has reached the switch-off voltage Vdec, then Vis=Vi+ and Vcs=Vi+. As a result, the bipolar transistor Ji is in the off state and the voltage Vi arrives at the switch Qi through a resistor Rij connecting the gate of the switch Qi to the potential Vi. The switch Qi is then in the off state/open: the bypass circuit 304i is open and does not allow the current to flow.


Alternatively to what is described in FIGS. 2 and 3, it is possible to use a second comparator that is not a hysteresis comparator.


It is also possible to use an individual voltage source for each comparator. The individual voltage sources may supply one and the same reference voltage or different reference voltages.


According to another alternative, it is possible to use a second comparator that is an inverting comparator. In this case, the second switch Qi′ may be for example an N-channel MOSFET transistor and the control means Ji may be an NPN bipolar transistor.


According to another alternative, it is possible not to use a voltage divider for the first comparator, as shown in FIG. 1a. In this case, the first comparator receives, as input, and compares with one another:

    • the voltage Vi across the terminals of the storage device DCi and
    • the balancing voltage Veq.


Alternatively or in addition, it is possible not to use a voltage divider for the second comparator. In this case, the second comparator receives, as input, and compares with one another:

    • the voltage Vi across the terminals of the storage device DCi and
    • the switch-off voltage Vdec.



FIG. 4 is a schematic depiction of an exemplary implementation of a monitoring module able to be implemented in the system according to the invention, and in particular in the system 200 of FIG. 2.


The monitoring module 400, shown in FIG. 4, takes as input, for each balancing device 202i, the control voltage Vcs supplied by the second comparator 206i and the voltage Vi.


It will be recalled that each voltage Vcs=Vi when the bypass circuit has not been switched off, and Vcs=Vi+ in the opposite case.


The monitoring module 400 comprises a weighted summer 402 taking a weighted sum of all of the Vcs.


The monitoring module 400 also receives the voltage V across the terminals of the storage assembly (V=Vn+−V1).


The monitoring module 400 furthermore comprises a voltage comparator 404 comparing the weighted sum voltage supplied by the weighted summer 402 with the voltage V across the terminals of the storage assembly.


As long as all of the bypass circuits have not all been switched off, the voltage supplied by the summer 402 will be lower than the voltage V across the terminals of the storage assembly. When all of the bypass circuits are switched off, the voltage supplied by the summer 402 will be equal to the voltage V across the terminals of the storage assembly.


The output of the comparator 404 may be used to signal the result of the comparison, for example with the aid of an indicator light 406 powered by the output of the comparator 404.


The comparator 404 may be referenced to the potentials (V1 and Vn+) across the terminals of the storage assembly 100.


Alternatively, the comparator 404 may compare the voltage supplied by the first summer 402 with a threshold voltage Vthreshold, taking into account a voltage δV representing a safety margin, such that:






V
threshold
=V−δV.


According to yet another alternative, the voltage δV representing a safety margin may be added to the weighted sum supplied by the summer 402, directly in said summer 402, or by another summer arranged in cascade with the summer 402.


The voltage δV representing a safety margin may be greater than or equal to 50 mV, this value typically representing the expected precision of the analogue electronics.



FIG. 5 is a schematic depiction of another exemplary implementation of a monitoring module able to be implemented in the system according to the invention, and in particular in the system 300 of FIG. 3.


The monitoring module 500 comprises, for each storage device DCi, a comparator 502i, referenced to the potentials Vn+ and V1 across the terminals of the storage assembly 100 and receiving:

    • at its positive input, the voltage Vis supplied by the first comparator 106i associated with said storage device DCi and
    • at its negative input, the voltage Vic supplied by the control means Ji associated with said storage device DCi.


Each comparator 502i therefore compares the voltages Vis and Vic such that, if Vis≤Vic, the output voltage of the comparator has the value V1, and, if Vis>Vic, the output voltage of the comparator has the value Vn+.


Each comparator 502i controls a switch, denoted Ki, which may be for example an NPN bipolar transistor, and which is open by default and which is closed when the voltage supplied by the comparator is equal to Vn+.


The switches K1, . . . , Kn, controlled by the comparators 5021, . . . , 502n, respectively, are connected to one another in series and to a resistor RK, between the potentials Vn+ and V1.


Thus, when there is at least one switch Ki that is open, then no current flows into the resistor RK, and the voltage VK at the negative terminal of the resistor RK has the value Vn+, this corresponding to a high state (non-zero voltage with respect to V1). When all of the switches Ki are closed, then a current flows through the resistor RK, and the voltage VK at the negative terminal of the resistor RK has the value V1, this corresponding to a low state (zero voltage with respect to V1).


The resistor RK is an arbitrary resistor with a value that is large enough, for example with a value of greater than 10 kΩ, to limit the current that passes through all of the switches K1, . . . , Kn.


This voltage VK may be used to monitor the operation of the balancing system, for example by turning on an indicator light (not shown in FIG. 5).


Alternatively, each comparator 502i may be local to the balancing device 302i of each storage device DCi.



FIG. 6 is a schematic depiction of a non limiting exemplary implementation of a storage module according to the invention.


The storage module 600, shown in FIG. 6, comprises a plurality of storage assemblies 1001, . . . , 100m each comprising a plurality of storage devices connected to one another in series.


The assemblies 1001, . . . , 100m may be connected to one another in series or in parallel.


In the example shown, each assembly 100j comprises “n” storage devices DC1j, . . . , DCnj.


A balancing device 302ij, such as for example the balancing device 302i of FIG. 3, is connected to each storage device DCij, 1≤i≤n and 1≤j≤m.


A monitoring module 400j, such as for example the monitoring module 400 of FIG. 4, is furthermore associated with each assembly 100j.


The storage module 600 may be used in a rechargeable electric or hybrid transport vehicle, which may be a bus, a car, a tram, a boat, a lorry, a cable car, a goods lift, a crane, etc.


The storage module 600 may also be used in an electrical installation, which may be:

    • an electric charging station for electric or hybrid transport vehicles,
    • a power supply station for a building, for a complex or for an electric/electronic communication device, or
    • a station for regulating, smoothing or buffer storing electrical energy.



FIGS. 7a-7d are nonlimiting exemplary implementations of a capacitive-effect electrical energy storage device.


Each storage device DCi may be any one of the storage devices described with reference to FIGS. 7a-7d.


The storage device DCi shown in FIG. 7a comprises a single supercapacitor C. It is this device example that has been considered in the examples described above with reference to FIGS. 1-6.


Of course, the invention is not limited to this example.


For example, the storage device DCi shown in FIG. 7b comprises a plurality of supercapacitors C connected in series.


The storage device DCi shown in FIG. 7c comprises a plurality of supercapacitors C connected in parallel.


The storage device DCi shown in FIG. 7d comprises a group of one of more supercapacitors C connected in series with a group of at least two supercapacitors connected in parallel with one another.


Of course, the invention is not limited to the examples described above.

Claims
  • 1. An analogue system for balancing a rechargeable electrical energy storage assembly comprising a plurality of capacitive-effect storage devices connected to one another in series, said system comprising, for each storage device, a balancing device including: a bypass circuit for said storage device, able to be controlled between a closed state and an open state; anda voltage comparator, called first comparator, arranged to control said bypass circuit into an open or closed state depending on the voltage at the terminals of said storage device and on a predetermined voltage, called balancing voltage;
  • 2. The system according to claim 1, characterized in that, for at least one, in particular each, storage device, at least one of the first and second comparators is referenced to the potentials on the terminals of said storage device, and is configured to supply, as output: in a first state: the smallest potential on the terminals of said storage device; andin a second state: the greatest potential on the terminals of said storage.
  • 3. The system according to claim 1, characterized in that it comprises, for at least one, in particular each, storage device: a voltage divider, called first voltage divider, supplying, to the first comparator, a first input voltage that is proportional to and lower than said voltage on the terminals of said storage device; and/ora voltage divider, called second voltage divider, supplying, to the second comparator, a second input voltage that is proportional to and lower than said voltage across the terminals of said storage device.
  • 4. The system according to claim 3, characterized in that, for at least one storage device, the voltage divider(s) is (are) dimensioned such that the first and second comparators perform a comparison of the input voltages at one and the same reference voltage, in particular supplied by one and the same single source.
  • 5. The system according to claim 1, characterized in that at least one of the first and second comparators is a hysteresis comparator.
  • 6. The system according to claim 1, characterized in that at least one, in particular each, bypass circuit comprises two switches in series, one controlled depending on the voltage supplied by the first comparator and the other controlled depending on the voltage supplied by the second comparator.
  • 7. The system according to claim 1, characterized in that at least one, in particular each, bypass circuit comprises a single switch, the balancing device further comprising a means for controlling said single switch depending on the voltages supplied by the first and second comparators.
  • 8. The system according to claim 7, characterized in that the control means comprises: a transistor that is in the blocked state by default, for example an NPN bipolar transistor, in particular when the second comparator is an inverting comparator; ora transistor that is in the on state by default, for example a PNP bipolar transistor, in particular when the second comparator is a non-inverting comparator.
  • 9. The system according to claim 1, characterized in that it further comprises a device for monitoring the operation of said system depending on the voltages supplied by the second comparators of all of the storage devices.
  • 10. The system according to claim 7, characterized in that it comprises a device for monitoring the operation of said system depending on the control voltages of the single switches of all of the bypass circuits.
  • 11. The system according to claim 7, characterized in that it comprises a device for monitoring the operation of said system depending on: the control voltages of all of the single switches, andthe voltages supplied by all of the first comparators.
  • 12. A rechargeable electrical energy storage module, comprising: at least one rechargeable electrical energy storage assembly, each comprising a plurality of capacitive-effect electrical energy storage devices connected to one another in series within said assembly; andfor at least one, in particular each, storage assembly, a balancing system according to claim 1.
  • 13. An electric or hybrid transport vehicle comprising one or more rechargeable electrical energy storage modules according to claim 12.
  • 14. An electrical installation, such as an electric charging station for electric or hybrid transport vehicles, or a power supply station for a building, for a complex or for an electric/electronic communication device, or a station for regulating or smoothing electrical energy, comprising one or more rechargeable electrical energy storage modules according to claim 12.
Priority Claims (1)
Number Date Country Kind
1661244 Nov 2016 FR national
PCT Information
Filing Document Filing Date Country Kind
PCT/EP2017/079251 11/15/2017 WO 00