• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for charging an electric storage battery from electric power supplied by an electric generator, wherein the battery is charged to a first state of maximum charge in a first mode of operation and to a second maximum state of charge, strictly less than the first state of maximum charge, in a second mode of operation, the method comprising the transition from the second mode of operation to the first mode of operation when a criterion using the temperature of the battery or the the ratio between a first datum representative of the available energy that can be supplied by the electric generator and a second datum representative of the energy consumed from the battery is filled.
    公开号:FR3060889A1
    申请号:FR1662966
    申请日:2016-12-21
    公开日:2018-06-22
    发明作者:Henri Zara;Thomas Fritsch;Franck Vial;Franck Al Shakarchi
    申请人:Commissariat a lEnergie Atomique CEA;Bubendorff SA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    Holder (s): COMMISSION FOR ATOMIC ENERGY AND ALTERNATIVE ENERGIES Public establishment, BUBENDORFF Public limited company.
    Extension request (s)
    Agent (s): CABINET BEAUMONT.
    METHOD AND DEVICE FOR CHARGING A BATTERY.
    FR 3 060 889 - A1 _ The invention relates to a method for charging an electric storage battery from electric energy supplied by an electric generator, in which the battery is charged to a first state of maximum charge in a first operating mode and at a second maximum load state, strictly lower than the first maximum load state, in a second operating mode, the method comprising switching from the second operating mode to the first operating mode when a criterion using the temperature of the battery or the ratio between a first datum representative of the available energy which can be supplied by the electric generator and a second datum representative of the energy consumed from the battery is filled.
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    B15496 - DD17372MR
    METHOD AND DEVICE FOR CHARGING A BATTERY
    Field
    The present application relates to a method for charging an electric storage battery of an autonomous system or of a system connected to the mains.
    Presentation of the prior art
    An autonomous system comprises an electrical or electromechanical system, a storage battery for the electrical supply of the electrical or electromechanical system and an electrical generator for charging the battery. An example of an autonomous system corresponds to an electric shutter powered by a battery, the charging of which is carried out by photovoltaic cells.
    It is generally desirable for the operating autonomy of the autonomous system to be as long as possible.
    For this purpose, it could be considered advantageous to charge the battery to the maximum as soon as the generator can supply electrical energy, in order to ensure maximum autonomy in the event that the generator supplies little electrical energy during A long period. However, it may be better to limit the maximum state of charge of the battery when the temperature of the battery is too high. Indeed, the combination of a high state of charge and a high temperature
    B15496 - DD17372MR accelerates the aging of the battery, whether at rest or in operation.
    For some applications, the battery of an autonomous system can be placed in a non-air conditioned space. In particular, when the battery is placed outside, the temperature of the battery can vary greatly during the year. For example, during the summer period, the temperature of the battery can rise sharply temporarily during the day.
    It is known to modify the maximum state of charge of the battery as a function of the ambient temperature, or even to disconnect the battery from the generator. However, this type of regulation is a regulation by reaction and not a regulation by anticipation. In some cases, it may not prevent battery degradation. In fact, when the state of charge of the battery is already high and the ambient temperature increases, a command to reduce the maximum state of charge of the battery remains ineffective, so that the battery will operate at high temperature. and with a high state of charge, and the battery life may decrease.
    summary
    An object of an embodiment is to overcome all or part of the drawbacks of the autonomous systems or of the systems connected to the sector described above.
    Another object of an embodiment is to increase the life of the battery.
    Another object of an embodiment is to increase the operating autonomy of the autonomous system.
    Another object of an embodiment is that the battery charge automatically adapts to environmental conditions.
    Thus, one embodiment provides a method of charging an electric storage battery from the electric energy supplied by an electric generator, in which the battery is charged at a first state of maximum charge.
    B15496 - DD17372MR in a first operating mode and at a second maximum load state, strictly lower than the first maximum load state, in a second operating mode, the method comprising switching from the second operating mode to the first operating mode when a criterion using the temperature of the battery or the ratio between a first datum representative of the energy available which can be supplied by the electric generator and a second datum representative of the energy consumed from the battery is fulfilled.
    According to one embodiment, the method comprises switching from the second operating mode to the first operating mode when the ratio between the first data representative of the available energy that can be supplied by the electric generator and the second data representative of the energy consumed from the battery becomes below a first threshold.
    According to one embodiment, the method comprises switching from the first operating mode to the second operating mode when the ratio between the first data representative of the available energy that can be supplied by the electric generator and the second data representative of the energy consumed from the battery becomes greater than the first threshold or a second threshold different from the first threshold.
    According to one embodiment, the battery is charged at a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, the method comprising changing from the third operating mode to the second operating mode when the ratio between the first datum and the second datum becomes less than a third threshold strictly above the first threshold.
    According to one embodiment, the method comprises passing from the second operating mode to the third operating mode when the ratio between the first datum and the second datum becomes greater than the third threshold, or to a
    B15496 - DD17372MR fourth threshold different from the third threshold and strictly above the first threshold.
    According to one embodiment, the first maximum charge state varies from 95% to 100%, the second maximum charge state varies from 50% to 95%, and the third maximum charge state varies from 20% to 50%.
    According to one embodiment, the first threshold varies from 1 to 3 and the third threshold varies from 3 to 15.
    According to one embodiment, the electric generator comprises photovoltaic cells.
    According to one embodiment, the first datum is determined from the measurement of the global irradiance received by the photovoltaic cells.
    According to one embodiment, the method comprises the determination of first values over a time window, the determination of the first datum comprising the determination of the average of the first values over the time window, the method further comprising the determination of second values, the determination of the second datum comprising the determination of the average of the second values over the time window.
    According to a fashion of achievement, the duration of the window temporal in the first operating mode East different the duration of the window temporal in the second fashion of operation.According to a fashion of achievement, the duration of the window
    time is changed after a period of battery operation.
    According to one embodiment, the method comprises passing from the first operating mode to the second operating mode when the temperature of the battery is higher than a first temperature value for a determined duration.
    According to one embodiment, the method comprises switching from the second operating mode to the first mode of
    B15496 - DD17372MR operation when the battery temperature is lower, for a determined period, than the first temperature value or a second temperature value, different from the first temperature value.
    According to one embodiment, the battery is charged at a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, the method comprising switching from the second operating mode to the third operating mode when the temperature of the battery is greater, for a determined period, than a third temperature value strictly greater than the first temperature value.
    According to one embodiment, the method comprises passing from the third operating mode to the second operating mode when the temperature of the battery is lower, for a determined period, at the third temperature value or at a fourth temperature value different from the third temperature value and strictly greater than the first temperature value.
    According to one embodiment, the method further comprises determining the state of health of the battery and maintaining the state of charge of the battery at the first state of maximum charge when the state of health decreases below d 'a state of health value.
    According to one embodiment, the charging of the battery is also prohibited as long as the temperature of the battery is greater than a fifth temperature value.
    According to one embodiment, the charging of the battery is also prohibited as long as the temperature of the battery is lower than a sixth temperature value.
    An embodiment also provides a system comprising an electric generator, a battery, a battery charging circuit from the electric energy supplied by the generator, and a charging circuit control module, the control module being suitable for controlling the load of the
    B15496 - DD17372MR battery at a first maximum charge state in a first operating mode and at a second maximum charge state, strictly lower than the first maximum charge state, in a second operating mode, the control module being adapted to pass from the second operating mode to the first operating mode when a criterion using the temperature of the battery or the ratio between a first datum representative of the available energy which can be supplied by the electric generator and a second datum representative of the energy consumed since the battery is filled.
    According to one embodiment, the control module is adapted to pass from the second operating mode to the first operating mode when the ratio between the first data representative of the available energy that can be supplied by the electric generator and the second data representative of the energy consumed from the battery becomes below a first threshold.
    According to one embodiment, the control module is adapted to pass from the first operating mode to the second operating mode when the ratio between the first data representative of the available energy that can be supplied by the electric generator and the second data representative of the energy consumed from the battery becomes greater than the first threshold or a second threshold different from the first threshold.
    According to one embodiment, the control module is adapted to control the charge of the battery to a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, and the control module is adapted to pass from the third operating mode to the second operating mode when the ratio between the first datum and the second datum becomes less than a second threshold strictly above the first threshold.
    According to one embodiment, the control module is adapted to pass from the second operating mode to the third
    B15496 - DD17372MR operating mode when the ratio between the first datum and the second datum becomes greater than the third threshold, or a fourth threshold different from the third threshold and strictly greater than the first threshold.
    According to one embodiment, the control module is adapted to pass from the first operating mode to the second operating mode when the temperature of the battery is higher than a first temperature value for a determined duration.
    According to one embodiment, the control module is adapted to pass from the second operating mode to the first operating mode when the temperature of the battery is lower, for a determined period, at the first temperature value or at a second value of temperature different from the first temperature value.
    According to one embodiment, the control module is adapted to control the charge of the battery to a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, and the control module is adapted to pass from the second operating mode to the third operating mode when the temperature of the battery is greater, for a determined period, than a third temperature value strictly greater than the first temperature value.
    According to one embodiment, the control module is adapted to pass from the third operating mode to the second operating mode when the temperature of the battery is lower, for a determined period, at the third temperature value or at a fourth value of temperature different from the third temperature value and strictly higher than the first temperature value.
    According to one embodiment, the electric generator comprises photovoltaic cells.
    B15496 - DD17372MR
    Brief description of the drawings
    These characteristics and advantages, as well as others, will be explained in detail in the following description of particular embodiments made without implied limitation in relation to the attached figures among which:
    Figure 1 shows, partially and schematically, an embodiment of an autonomous system;
    FIG. 2 is an operating diagram of an embodiment of a first method of charging the battery implemented by the autonomous system shown in FIG. 1;
    FIG. 3 represents curves of evolution as a function of time of the ratio between the available energy that can be supplied by the electric generator of the autonomous system and the energy consumed by the autonomous system of FIG. 1, according to different operating conditions;
    FIG. 4 is an operating diagram of an embodiment of a second method of charging the battery implemented by the autonomous system shown in FIG. 1;
    FIG. 5 represents curves of evolution as a function of time, obtained by simulation for the autonomous system of FIG. 1 under particular meteorological conditions, of the available energy which can be supplied by the electric generator of the autonomous system, of the setpoint state of charge (SoC) of the autonomous system battery, state of charge of the autonomous system battery, the number of hours for which the autonomous system battery temperature is above 40 ° C, the state of health of the battery of the autonomous system when the charging method illustrated in FIG. 4 is not implemented and the state of health of the battery of the autonomous system when the charging method illustrated in FIG. 4 is implemented;
    FIG. 6 represents evolution curves similar to the curves represented in FIG. 5 for different meteorological conditions;
    B15496 - DD17372MR FIG. 7 is an operating diagram of another embodiment of the second method of battery charging implemented by the autonomous system shown in FIG. 1;
    FIG. 8 represents curves of evolution as a function of time, obtained by simulation for the autonomous system of FIG. 1 under particular meteorological conditions, of the available energy which can be supplied by the electric generator of the autonomous system and of the state of charge of the battery of the autonomous system when the charging method illustrated in FIG. 4 is implemented; and FIG. 9 represents curves of evolution as a function of time, obtained by simulation for the autonomous system of FIG. 1 under particular meteorological conditions, of the ratio between the available energy which can be supplied by the electric generator of the autonomous system and the energy consumed by the autonomous system of FIG. 1, and of the state of charge of the battery for two threshold values implemented by the charging method illustrated in FIG. 4. Detailed description
    The same elements have been designated by the same references in the different figures. For the sake of clarity, only the elements which are useful for understanding the embodiments described have been shown and are detailed. In particular, the structure of an electric accumulator of a storage battery is well known and is not described in detail. In the following description, when referring to qualifiers of absolute position, such as the terms forward, backward, up, down, left, right, etc., or relative, such as the terms above, below, top , lower, etc., or to orientation qualifiers, such as the terms horizontal, vertical, etc., reference is made to the orientation of the figures. Unless specified otherwise, the expressions approximately, appreciably, and of the order of mean to the nearest 10%, preferably to the nearest 5%.
    B15496 - DD17372MR
    FIG. 1 represents an embodiment of an autonomous system 10 comprising:
    an electrical or electromechanical system 12; at least one battery 14 of electric accumulators allowing the electrical supply of the electrical or electromechanical system 12;
    an electric generator 16 for charging the battery 14;
    a charging circuit 18 connected between the electric generator 16 and the battery 14;
    a module 20 for controlling the charging circuit 18; a battery temperature sensor 22 connected to the control module 20;
    a circuit 24 for measuring the voltage across the generator 16 and the current supplied by the generator 16, connected to the control module 20; and a circuit 26 for measuring the voltage across the battery 14 and the current supplied by the battery 14, connected to the control module 20.
    The electrical or electromechanical system 12 can correspond to any type of system requiring an electrical supply. For example, the electrical or electromechanical system 12 corresponds to an electric shutter, an electric gate, a window with motorized opening, or an element of urban furniture requiring an electrical supply, for example a parking meter or lighting equipment. public.
    The electric generator 16 can correspond to any type of electric energy source. The electric generator 16 can correspond to a generator or to an electric production center connected to the battery 14 by the electric distribution network. Preferably, the electric generator 16 is adapted to supply electrical energy from renewable energy, for example solar energy, wind energy, hydraulic energy or energy.
    B15496 - DD17372MR geothermal. By way of example, the electric generator 16 comprises photovoltaic cells adapted to output a direct current and / or a direct electric voltage when they receive incident solar radiation, the photovoltaic cells being connected together, in series or in parallel, by means of an electrical circuit and / or which can be arranged on one or more photovoltaic panels, all the photovoltaic cells connected to each other being called photovoltaic power station 16 in the following description. According to another example, the electric generator 16 comprises at least one wind turbine or a hydraulic device.
    The battery 14 may correspond to an electric storage battery of any type, in particular a lithium battery, a nickel metal hydride battery or a lead battery. The electric accumulators of the battery 14 can be mounted in series and / or in parallel.
    The control module 20 can correspond to a dedicated circuit and / or can comprise a processor, for example a microprocessor or a microcontroller, adapted to execute instructions of a computer program stored in a memory.
    The charging circuit 18 is a circuit interposed between the electric generator 16 and the battery 14. In the case where the electric generator 16 comprises photovoltaic cells, the charging circuit 18 can only correspond to a circuit preventing the discharge of the battery 14 in photovoltaic cells when these do not produce electrical energy. More generally, the charging circuit 18 can be adapted to convert the electric power supplied by the generator 16 into an electric power suitable for charging the battery 14. The charging circuit 18 comprises, for example, a voltage converter , for example a serial chopper converter (Buck converter).
    The control module 20 is adapted to control the charging circuit 18 to implement a charging method
    B15496 - DD17372MR adapted to the specifics of the battery 14. The control module 20 is, for example, adapted to implement a process for finding the maximum power point (MPPT, English acronym for Maximum Power Point Tracking). The control module 20 is further adapted to control the charging circuit 18 to prevent the battery 14 from being charged by the electric generator 16.
    According to one embodiment, the temperature sensor 22 is arranged in contact with the accumulators of the battery 14. According to one embodiment, several temperature sensors 22 are present and arranged in contact with the accumulators of the battery 14 at different locations. The temperature of the battery 14 can then correspond to the highest temperature among the temperatures measured by the temperature sensors, or to an average of the temperatures measured by the temperature sensors. According to another embodiment, the temperature sensor 22 is adapted to measure the ambient temperature, that is to say the temperature in the vicinity of the battery 14, for example more than 10 cm from the battery 14. The module control 18 is then adapted to estimate the temperature of the battery 14 from the measured ambient temperature, using graphs stored in memory.
    The control module 20 can be adapted to determine the electric power supplied by the generator 16 from measurements of the voltage and current supplied by the measurement circuit 24. The control module 20 is, moreover, adapted to estimate the state of charge, called SOC (English acronym for State Of Charge) of the battery 14, for example by means of charts stored in memory, from the measurements of the temperature of the battery 14 supplied by the temperature sensor 22 and measurements of the voltage at the terminals of the battery 14 and of the current delivered by the battery 14 supplied by the measurement circuit 26.
    According to one embodiment, the control module 20 simultaneously implements two methods of controlling the charging circuit 18.
    B15496 - DD17372MR
    According to one embodiment, the first control method aims to prevent any charging operation of the battery 14 only if the temperature of the battery 14 is too high or too low, to avoid degradation of the battery 14.
    FIG. 2 represents a more detailed operating diagram of an embodiment of the first control method.
    In step 30, the control module 20 checks whether the temperature of the battery 14 is between a minimum temperature T m -j_ n and a maximum temperature T max . By way of example, the minimum temperature T m -j_ n is equal to 0 ° C. By way of example, the maximum temperature T max is between 40 ° C and 60 ° C, preferably between 45 ° C and 50 ° C. If the temperature of the battery 14 is between the temperatures T m j_ n and T max , the process
    continues to stepcontinues to step 34. 32. In the case opposite, the process is At the stage 32 , the module of command 2 0 authorizes a charging operationstep 30. of battery 14. The process continues to At the stage 34, , the module of command 2 0 prevents any charging operation of battery 14. The process continues to
    step 30.
    According to one embodiment, the second method of controlling the charging circuit 18 aims, for a battery charging operation, to select a setpoint for the maximum state of charge that the battery 14 can reach from a first value called the setpoint low, a second value called intermediate setpoint greater than the lower setpoint and a third value called high setpoint greater than the intermediate setpoint. The low setpoint, preferably varying from 20% to 50%, for example equal to 30%, is selected when there is a low risk that the energy supplied by the generator 16 of the autonomous system 10 and which can be used for the charging the battery 14 cannot compensate for the energy supplied by the battery 14 for supplying the system
    B15496 - DD17372MR electrical or electromechanical 12. The intermediate setpoint, preferably varying from 50% to 95%, for example equal to 90%, is selected when there is always a low risk, but a little higher than in the case above, that the energy supplied by the generator 16 of the autonomous system 10 and which can be used for charging the battery 14 cannot compensate for the energy supplied by the battery 14 for supplying the electrical or electromechanical system 12. The high setpoint, preferably varying from 95% to 100%, for example equal to 100%, is selected in the other cases.
    According to one embodiment, the modification of the maximum charge state setpoint is carried out by comparing thresholds the Esol / Eutil ratio between a first Esol datum, called available energy, representative of the energy that can be supplied by the generator. 16 on a first analysis time window, and a second Eutil datum, called energy consumed, representative of the energy consumed by the electrical or electromechanical system 12 on a second analysis window, which may be identical to the first window d or different from the first analysis window.
    Table I below indicates the value of the setpoint for the maximum state of charge of the battery 14 as a function of the comparison of the Esol / Eutil ratio with thresholds according to one embodiment:
    Esol / Eutil <low threshold Low threshold <Esol / Eutil <high threshold Esol / Eutil> high threshold Low setpoint X Intermediate setpoint X
    B15496 - DD17372MR
    High setpoint X
    Table I
    In the case where the electric generator 16 comprises photovoltaic cells, the determination of the available energy Esol can comprise the determination, for several consecutive days, for example 10 days, of the global irradiance received by the photovoltaic cells.
    The global irradiance or energy illumination corresponds to the power of electromagnetic radiation received by an object per unit of area. According to one embodiment, the global irradiance measured is that of the useful spectrum of the sunlight received by the photovoltaic cells. In a given plane, for example that of photovoltaic panels comprising photovoltaic cells, the global irradiance is the sum of three components:
    direct irradiance, which comes directly from the sun, this component being zero when the sun is hidden by clouds or by an obstacle;
    the diffuse irradiance which corresponds to the radiation received from the sky, except for direct radiation; and the reflected irradiance which corresponds to the radiation reflected by the ground and the environment.
    The global irradiance can be determined from the measurement of the short-circuit current of the photovoltaic power plant 16.
    According to another embodiment, in particular in the case where the electric generator 16 does not include photovoltaic cells, the control module 20 can determine the available energy Esol on an analysis window from measurements of the voltage and the current supplied by the measuring circuit 24.
    According to one embodiment, in the case where the supply voltage of the electrical or electromechanical system 12 is constant, the energy consumed Eutil can be determined by measuring the current consumed by the electrical system or
    B15496 - DD17372MR electromechanical 12. According to one embodiment, in the case where the supply voltage of the electrical or electromechanical system 12 is not constant, the energy consumed Eutil can be determined by measuring the current consumed by the system electric or electromechanical 12 and the measurement of the supply voltage of the electric or electromechanical system 12. When the electric or electromechanical system 12 includes a rolling shutter, the energy consumed Eutil can be determined by measuring the current consumed by the electric motor rolling shutter training each time the rolling shutter is used during the analysis window.
    According to another embodiment, the control module 20 is suitable for determining the energy consumed Eutil by counting the number of activations of the electrical or electromechanical system 12 on the analysis window and by determining the product between this number of activations and an estimate of the energy consumed for each activation, or activation energy, stored in memory. This advantageously makes it possible not to have to directly measure the energy consumed by the electrical or electromechanical system 12.
    When the electrical or electromechanical system 12 comprises a rolling shutter, the activation energy depends in particular on the size of the shutter which is not known a priori by the control module 20. The activation energy can be estimated by the control module 20 by the duration of the stroke going from the opening to the closing of the rolling shutter or from the closing to the opening of the rolling shutter. According to one embodiment, a table of correspondence between the duration of opening or closing of the shutter and the activation energy for all the possible sizes of rolling shutter is stored in a memory of the control module 20. When the shutter is used for the first time, the control module 20 is adapted to measure the duration of opening or closing of the shutter and to select from the table the appropriate value of the activation energy. According to another example, the activation energy can be measured once, for example at
    B15496 - DD17372MR installing the roller shutter, for example by measuring the current consumed by the roller shutter and measuring the supply voltage of the roller shutter during activation of the roller shutter.
    The thresholds to which the Esol / Eutil report is compared can be determined beforehand and stored in a memory of the control module 20. The thresholds depend on the intended application and in particular on the importance attached to the constraint of operating autonomy of the autonomous system, also called continuity of service, and with the constraint of maximizing the life of the battery 14.
    FIG. 3 represents evolution curves C1, C2 and C3, obtained by simulation, of the Esol / Eutil ratio in an embodiment in which the electric generator 16 comprises photovoltaic cells oriented respectively to the north, to the east and to the south and in which the electrical or electromechanical system 12 comprises a shutter. In this example, the Esol / Eutil ratio changes from 1 to 27.
    From numerous simulations similar to that of FIG. 3, the inventors have defined thresholds in an embodiment in which the electric generator 16 comprises photovoltaic cells and in which the electrical or electromechanical system 12 comprises a rolling shutter.
    According to one embodiment of a method for controlling the value of the setpoint of the maximum state of charge of the battery 14 according to the preceding table I, the maximum state of charge that can be reached by the battery 14 is the high setpoint when the Esol / Eutil ratio is strictly lower than the low threshold, between 1 and 3. The low threshold makes it possible to maintain a margin of energy resource to ensure continuity of service. The maximum state of charge that the battery 14 can reach is the intermediate setpoint when the Esol / Eutil ratio is strictly greater than the low threshold and less than or equal to the high threshold between 3 and 15. The high threshold makes it possible to maintain a margin of energy resource so that the state of charge
    B15496 - DD17372MR can easily go back to 100% in the event of irradiance conditions becoming less favorable. The maximum state of charge that the battery 14 can reach is the low setpoint when the Esol / Eutil ratio is strictly above the high threshold. This threshold makes it possible to maintain a high energy resource margin. This makes it possible both to guarantee the possibility of rapidly raising the state of charge to the intermediate setpoint in the event of irradiance conditions becoming less favorable and at the same time preventing the overheating conditions. This threshold is preferably defined for the most penalizing environmental conditions vis-à-vis the high temperatures of the battery 14.
    FIG. 4 represents an operating diagram of an embodiment of the second method of controlling the charging circuit 18.
    Step 40 corresponds to an initialization state in which the control module 20 is automatically placed when the autonomous system 10 is started for the first time, for example when the autonomous system is powered up 10. According to one embodiment, when step 40, an operation for charging the battery 14 is authorized according to an operating mode defined by default, for example at the intermediate setpoint. This allows, advantageously, if the battery 14 is partially discharged when the autonomous system 10 is powered up, immediately begin to complete its charge. The process continues at step 42.
    In step 42, the control module 20 determines new values of the available energy Esol and of the energy consumed Eutil. The control module 20 then determines a new value of the Esol / Eutil ratio.
    According to one embodiment, to determine the ratio Esol / Eutil, the control module 20 determines the average of the values of the available energy Esol determined on an analysis window of several consecutive days, preferably 10 days, to be representative of a global trend of evolution
    B15496 - DD17372MR weather conditions. To determine the Esol / Eutil ratio, the control module 20 determines the average of the values of the energy consumed Eutil determined on the analysis window for several consecutive days, preferably 10 days, to be representative of an overall trend of consumption of the electrical or electromechanical system 12.
    The values of the available energy Esol are, for example, determined at regular intervals, preferably every 5 minutes. It is advantageous that the measurement step is less than 60 minutes so that the determination of the available energy Esol is little modified by large variations over short durations of the irradiance, for example when the sun is briefly hidden by clouds. . The values of the energy consumed Eutil can be determined each time the electrical or electromechanical system is used 12.
    For example, the determination of a new value of the Esol / Eutil ratio is carried out at each new value of the available energy Esol or of the energy consumed Eutil with the previous measurements of the available energy Esol or of the energy consumed Eutil carried out during the analysis window which ends with the last measurement carried out. According to another example, the determination of a new value of the Esol / Eutil ratio is carried out at regular intervals, preferably once a day with the measurements of the available energy Esol and of the energy consumed Eutil carried out during the window d 'analysis.
    According to one embodiment, at the start of the operation of the autonomous system 10, the Esol / Eutil ratio is determined with the values measured over the number of days of operation of the autonomous system 10 until the duration of the analysis window be reached. The process continues at step 44.
    In step 44, the control module 20 compares the new value of the Esol / Eutil ratio with the high threshold. If the Esol / Eutil ratio is strictly greater than the high threshold, the process continues at step 46. If the Esol / Eutil ratio is
    B15496 - DD17372MR less than or equal to the high threshold, the process continues at step 48.
    In step 46, the control module 20 goes into an operating mode, called low mode, in which the maximum state of charge instruction of the battery 14 is the low instruction. The method of charging the battery 14, that is to say the control of the charging circuit 18 by the control module 20, can be specific in the low mode. By way of example, the maximum charging current of the battery 14 can be maximum. As a variant, the method for charging the battery 14 in the low mode may be identical to the method for charging the battery in the intermediate mode and / or the high mode, only the maximum state of charge instruction for the battery being different. The low operating mode continues as long as there is no change to another operating mode and as long as there is no load interruption requested by the first operating method described above. The process continues at step 42.
    In step 48, the control module 20 compares the new value of the Esol / Eutil ratio with the low threshold. If the Esol / Eutil ratio is strictly greater than the low threshold, the method continues at step 50. If the Esol / Eutil ratio is less than or equal to the low threshold, the method continues at step 52.
    In step 50, the control module 20 goes into an operating mode, called intermediate mode, in which the maximum charge state instruction for the battery 14 is the intermediate instruction. The method for charging the battery 14, that is to say the control of the charging circuit 18 by the control module 20, can be specific in the intermediate operating mode. As a variant, the method for charging the battery 14 in the intermediate mode may be identical to the method for charging the battery in the low mode and / or the high mode, only the maximum state of charge charge of the battery being different. Intermediate mode continues as long as it
    B15496 - DD17372MR there is no change to another operating mode and as long as there is no load interruption requested by the first operating method described above. The process continues at step 42.
    In step 52, the control module 20 goes into an operating mode, called high mode, in which the maximum state of charge instruction of the battery 14 is the high instruction. The method of charging the battery 14, that is to say the control of the charging circuit 18 by the control module 20, can be specific in the high mode. For example, the maximum charging current of the battery 14 can be limited. As a variant, the method of charging the battery 14 in the high mode can be identical to the method of charging the battery in the low mode and / or the intermediate mode, only the maximum state of charge charge of the battery being different. The high mode continues as long as there is no change to another operating mode and as long as there is no load interruption requested by the first operating method described above. The process continues at step 42.
    The comparison steps 44 and 48 can be carried out at each determination of a new value of the Esol / Eutil ratio or at regular intervals, preferably once a day.
    To assess an improvement in the life of the battery 14, one can determine the state of health or SOH (acronym for State Of Health) of the battery 14. The determination of the state of health of the battery can be performed on the basis of battery aging models 14 which take into account in particular:
    - the amount of energy delivered by the battery 14 over its life;
    - the time spent by the battery 14 at different temperature levels;
    - the operating time of the autonomous system 10.
    B15496 - DD17372MR
    An example of a method for determining the state of health of a battery is described in the work entitled Electrochemical Energy Storage for Renewable Sources and Grid Balancing in chapter 20 entitled Battery management and battery diagnostics written by Angel Kirchev (2015 Elsevier BV, pages 411-435).
    FIG. 5 represents evolution curves CEsol, CSOC, RSOC, C40, CSOH1 and CSOH2 over a year obtained by simulations for an autonomous system 10 comprising photovoltaic cells oriented to the south. The simulations are presented on the irradiance weather database on a particular site.
    The CEsol curve is the evolution curve as a function of the time of the available energy Esol that can be supplied by the generator 16 of the autonomous system 10. The CSOC curve is the evolution curve as a function of the time of the state setpoint of charge of the battery 14. The RSOC curve is the evolution curve as a function of time of the state of charge of the battery 14. The C40 curve is the evolution curve as a function of time of the number of hours for which the temperature of the battery 14 is greater than 40 ° C. The curve CSOH1 is the evolution curve as a function of time of the state of health of the battery 14 when the charging method illustrated in FIG. 4 is not implemented and the curve CSOH2 is the evolution curve in as a function of time of the state of health of the battery 14 when the charging method illustrated in FIG. 4 is implemented.
    As shown by the RSOC curve, the state of charge of the battery 14 is at 30% most of the time, except for a short off-season period when the irradiance conditions become more unfavorable (i.e. the Esol / Eutil ratio is lower 10). This results in a rapid rise in the state of charge of the battery to 90%. It can be checked that this period corresponds to moderate battery temperatures (below 40 ° C). The gain on the aging of the battery is highlighted by considering the time spent at high temperature, i.e.
    B15496 - DD17372MR
    23 a decrease of 1% the state of health of the battery 14 when the charging process illustrated in Figure 4 is implemented and a decrease of 7% the state of health of the battery 14 when
    the charging method illustrated in FIG. 4 is not implemented.
    FIG. 6 represents evolution curves analogous to the curves represented in FIG. 5, obtained by simulations over one year for an autonomous system 10 comprising photovoltaic cells oriented to the north, that is to say in a more unfavorable exposure situation. . As the RSOC curve shows, the state of charge is 90% at interseason and 30% in summer for a switchover criterion to Esol / Eutil equal to 10. In this case the temperature of the battery 14 is always moderate ( i.e. less than 40 ° C). However, the implementation of the charging method illustrated in FIG. 4 makes it possible to reduce the aging of the battery since a 2% decrease in the state of health of the battery 14 is observed when the charging method illustrated in FIG. 4 is implemented and a 7% decrease in the state of health of the battery 14 when the charging method illustrated in FIG. 4 is not implemented.
    As it appears on the simulations, in a situation of strong sunshine where the battery temperature reaches values favoring aging (i.e. above 40 ° C), the state of charge is limited to 30%, and in low light situations where battery temperatures remain limited, the state of charge is 90%.
    One explanation for the gain in battery aging is that the charging process tends to command the lowest possible charge rate while satisfying the service continuity criterion. The aging of the battery 14 is then reduced, all the more so as the temperature is high.
    It can be observed that aging with the implementation of the charging method illustrated in FIG. 4 is more pronounced for the simulations illustrated in FIG. 6 concerning an exposure to the north of the photovoltaic cells of the autonomous system 10 than for the simulations illustrated in FIG. 5 which
    B15496 - DD17372MR relate to an exposure to the south of the photovoltaic cells of the autonomous system 10. One explanation is that the state of charge of the battery 14 is higher in the case of the north exposure than of the south exposure. The more favorable temperature conditions in the case of northern exposure therefore do not improve the battery life because the state of charge remains high for a longer period. The charging method illustrated in FIG. 4 advantageously makes it possible to increase the life of the battery even in this case.
    In general, at the end of life, the maximum storage capacity of the batteries gradually deteriorates. It may then no longer be possible to ensure continuity of service for the autonomous system. It may then no longer be advisable to maintain a partial charge regime for the battery 14, otherwise the capacity of the batteries may not be fully exploited. According to one embodiment, from a certain level of state of health, the battery charge is permanently authorized to 100% so as to ensure continuity of service until the ultimate aging of the battery.
    FIG. 7 is an operating diagram of another embodiment of the second method of battery charging implemented by the autonomous system 10 represented in FIG. 1. The steps common with the embodiment of the second charging method described above in connection with Figure 4 are indicated with the same references.
    The method begins at the initialization step 40 described above. At this stage, the control module 20 also initializes the state of health of the battery to 100%. The process continues at step 60.
    In step 60, the control module 20 compares the state of health of the battery 14 with a threshold of between 50% and 70%, for example equal to 60%. If the state of health is strictly above the threshold, the process continues at step 42 described above. If the state of health is less than or equal to the threshold, the method continues at step 52 described above.
    B15496 - DD17372MR
    After the execution of steps 46, 50 and 52 described previously, the method does not continue to step 42 as for the embodiment of the control method described previously in relation to FIG. 4, but, in the present mode embodiment, the method continues at step 62.
    In step 62, the control module 20 determines the state of health of the battery 14. According to one embodiment, to determine the state of health, the control module 20 can determine the number of hours spent by the battery 14 between 30 ° C and 40 ° C, the number of hours spent by the battery 14 between 40 ° C and 50 ° C and the number of hours spent by the battery 14 between 50 ° C and 60 ° C. The control module 20 can, moreover, determine the amount of energy supplied by the battery 14 since it was put into service. The control module 20 can also determine the total duration of operation of the battery 14. The process continues at step 60.
    According to another embodiment, the determination of the state of health of the battery 14 can be obtained by the determination of the energy consumed by the electrical or electromechanical system 12 between two identifiable levels of the state of charge of the battery 14, for example 90% and 30%, then by comparison of this energy with the initial performances of the battery 14. According to another embodiment, the determination of the state of health can include counting the number of activations of the system electrical or electromechanical 12 between two identifiable levels of the state of charge of the battery 14, for example 90% and 30%, then by comparison of this energy with the initial performances the battery 14. The determination of a new value of the state of health can be implemented periodically (for example every 500 activations of the electrical or electromechanical system 12) during a period when the irradiance is high d e so that the state of charge of the battery 14 can drop to the low setpoint, for example 30%. In the case where the state of charge of the battery 14 never drops to the low setpoint, for example in the case of a
    B15496 - DD17372MR unfavorable exposure, the state of health may not be calculated by the method comprising counting the number of activations of the electrical or electromechanical system 12 between two identifiable levels of the state of charge of the battery 14, for example 90% and 30%, because the state of charge of the battery 14 is permanently high (at the intermediate setpoint, for example 90%, or at the high setpoint, for example 100%), but can be calculated by d other method s.
    Advantageously, the implementation of the charging methods described above does not require the determination of the date of the day by the control module 20. The determination of the operating mode of the autonomous system 10 is carried out automatically when it is started up. .
    Particular embodiments have been described. Various variants and modifications will appear to those skilled in the art.
    In particular, in the embodiments described above, the duration of calculation of the average of the available energy Esol and of the energy consumed Eutil is 10 days regardless of the operating mode of the autonomous system 10. However, this duration may be different depending on the operating mode of the control module 20.
    When it is desired to favor continuity of service, it may be desirable to increase the reactivity of the control module 20 when it is a question of going towards the high states of charge of the battery 14. In this case, the calculation time in step 42 of the average of the available energy Esol and the energy consumed Eutil may be shorter in the high mode than in the intermediate mode and may be shorter in the mode intermediate than in the low mode. For example, in the high mode, in which the maximum state of charge instruction of the battery 14 is for example 100%, the duration of calculation of the average of the available energy Esol and of the energy Eutil consumption can be less than 10 days, for example equal to 6 days. In the intermediate operating mode, in which
    B15496 - DD17372MR the maximum charge state setpoint is for example 90%, the duration of calculation of the average of the available energy Esol and of the energy consumed Eutil can be less than 10 days, for example equal to 8 days and in the low operating mode, in which the maximum charge state setpoint is, for example, 30%, the duration for calculating the average of the available energy Esol and the energy consumed Eutil can be left at 10 days.
    When it is desired to favor the life of the battery over continuity of service, it may be desirable to reduce the reactivity of the control module 20 when it is a question of moving towards high states of charge. In this case, the calculation time in step 42 of the average of the available energy Esol and of the energy consumed Eutil may be longer in the high mode than in the intermediate mode and may be longer in the mode intermediate than in the low mode. For example, in the high operating mode, the duration for calculating the average of the energy available Esol and the energy consumed Eutil can be left to 10 days. In the intermediate operating mode, the average time for calculating the available energy Esol and the energy consumed Eutil can be less than 10 days, for example equal to 8 days and in the low operating mode, the duration calculation of the average of the available energy Esol and the energy consumed Eutil can be less than 10 days, for example equal to 6 days.
    In particular, in the embodiments described above, the duration of the analysis window for calculating the average of the available energy Esol and of the energy consumed Eutil is constant during the operation of the autonomous system 10. However , this duration of the analysis window may not be optimal in particular depending on the geographic location of the autonomous system 10 and the exposure of the autonomous system 10. In fact, it has generally been obtained after numerous attempts to take account of the most unfavorable cases.
    FIG. 8 represents curves of evolution CEsol and RSOC as a function of time, obtained by simulation in
    B15496 - DD17372MR particular weather conditions, respectively of the available energy which can be supplied by the generator 16 of the autonomous system 10 and of the state of charge of the battery 14, when the charging method illustrated in FIG. 4 is implemented. As it can be seen in this figure, the state of charge switches twice to 90% while the Esol / Eutil ratio is practically always greater than 10. This means that the duration of the analysis window is not optimal and that it should be increased. Indeed, by increasing the duration of the analysis window, the smoothing effect is increased, which makes it possible to eliminate the short periods when the module 20 controls the rise in the state of charge of the battery 14 to 90% without real necessity.
    According to one embodiment, the duration of the analysis window used for calculating the average of the available energy Esol and of the energy consumed Eutil can be modified during the operation of the autonomous system 10. According to a mode of realization, when the autonomous system 10 is put into service for the first time, the value of the duration of the analysis window used is a value stored in a memory of the control module 20. The control module 20 determines a new value of the duration of the analysis window as a function of the behavior of the autonomous system 10 for a certain period, for example a year, so that the autonomous system 10 has operated in all seasons.
    The control module 20 can determine, at the end of the period, the states of charge actually reached and the values of the Esol / Eutil ratios for each level of state of charge. The control module 20 can then update the durations of the analysis windows for each high, intermediate and low mode when these durations are different according to the operating mode of the autonomous system, or update the duration of the analysis when this is common to the high, intermediate and low modes. The present embodiment makes it possible to improve the reduction in the aging of the battery.
    B15496 - DD17372MR
    According to another embodiment, it is possible to favor more or less the low states of charge. When it is desired to favor continuity of service, it is possible to select rather high values for the low and high thresholds. For example, the low threshold can be equal to 2 and the high threshold can be equal to 10. When it is desired to promote the life of the battery 14, it is possible to select rather low values for the low and high threshold. . For example, the low threshold can be 1.5 and the high threshold can be 5.
    FIG. 9 represents an evolution curve of the Esol / Eutil ratio, a SOC1 curve of evolution of the state of charge of the battery when the high threshold is equal to 10 and a SOC2 curve of evolution of the state of battery charge when the high threshold is equal to 15. Note that for the SOC2 curve, the state of charge of the battery is more frequently maintained at 90% than for the SOC1 curve.
    According to another embodiment, in the case where the electric generator 16 is adapted to supply an electric energy which is substantially constant over time, for example when the electric generator 16 corresponds to a generator or to an electric production center connected to the battery 14 by the electrical distribution network, the management of the state of charge of the battery can be deduced from the temperature of the battery by measuring the daily number of hours spent above a temperature threshold. According to one embodiment, if this number is less than a threshold number of hours, the maximum state of charge instruction is the intermediate instruction, otherwise the state of charge instruction is the low instruction. For example 2 hours in a 24 hour period at a temperature above 40 ° C results in a charge with the low setpoint (for example 0% to 50%), otherwise a charge with the intermediate setpoint (for example 50% to 95% ).
    In addition, in the embodiments described above, the modification of the maximum charge state setpoint from the low setpoint to the intermediate setpoint is
    B15496 - DD17372MR performed by comparing the Esol / Eutil ratio to the high threshold. As a variant, the modification of the maximum charge state setpoint from the low setpoint to the intermediate setpoint can be carried out when the Esol / Eutil ratio becomes lower than a first high threshold while the modification of the state setpoint maximum load from the intermediate setpoint to the low setpoint can be achieved when the Esol / Eutil ratio becomes greater than a second high threshold different from the first high threshold. In addition, in the embodiments described above, the modification of the maximum charge state setpoint from the intermediate setpoint to the high setpoint is carried out by comparing the Esol / Eutil ratio at the low threshold. As a variant, the modification of the maximum charge state setpoint from the intermediate setpoint to the high setpoint can be carried out when the Esol / Eutil ratio becomes less than a first low threshold while the modification of the state setpoint maximum load from the high setpoint to the intermediate setpoint can be achieved when the Esol / Eutil ratio becomes greater than a second low threshold different from the first low threshold.
    B15496 - DD17372MR
    权利要求:
    Claims (29)
    [1" id="c-fr-0001]
    1. Method for charging a battery (14) of electric accumulators from the electric energy supplied by an electric generator (16), in which the battery is charged at a first state of maximum charge in a first mode of operation and at a second maximum charge state, strictly lower than the first maximum charge state, in a second operating mode, the method comprising switching from the second operating mode to the first operating mode when a criterion using the temperature of the battery (14) or the ratio between a first datum (Esol) representative of the available energy that can be supplied by the electric generator and a second datum (Eutil) representative of the energy consumed from the battery is filled.
    [2" id="c-fr-0002]
    2. Method according to claim 1, comprising the transition from the second operating mode to the first operating mode when the ratio between the first datum (Esol) representative of the energy available which can be supplied by the electric generator and the second datum (Eutil ) representative of the energy consumed from the battery becomes less than a first threshold.
    [3" id="c-fr-0003]
    3. Method according to claim 2, comprising switching from the first operating mode to the second operating mode when the ratio between the first datum (Esol) representative of the energy available which can be supplied by the electric generator and the second datum (Eutil ) representative of the energy consumed from the battery becomes greater than the first threshold or a second threshold different from the first threshold.
    [4" id="c-fr-0004]
    4. Method according to claim 2 or 3, wherein the battery (14) is charged at a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, the method comprising passing from the third mode of operation in the second mode of
    B15496 - DD17372MR operates when the ratio between the first datum and the second datum becomes less than a third threshold strictly above the first threshold.
    [5" id="c-fr-0005]
    5. Method according to claim 4, comprising the transition from the second operating mode to the third operating mode when the ratio between the first datum and the second datum becomes greater than the third threshold, or to a fourth threshold different from the third threshold and strictly higher at the first threshold.
    [6" id="c-fr-0006]
    6. Method according to any one of claims 4 to 5, in which the first maximum charge state varies from 95% to 100%, in which the second maximum charge state varies from 50% to 95%, and in which the third maximum state of charge varies from 20% to 50%.
    [7" id="c-fr-0007]
    7. Method according to any one of claims 4 to 6, in which the first threshold varies from 1 to 3 and in which the third threshold varies from 3 to 15.
    [8" id="c-fr-0008]
    8. Method according to any one of claims 2 to 7, wherein the electric generator (16) comprises photovoltaic cells.
    [9" id="c-fr-0009]
    9. The method of claim 8, wherein the first datum is determined from the measurement of the overall irradiance received by the photovoltaic cells.
    [10" id="c-fr-0010]
    10. Method according to any one of claims 2 to 9, comprising the determination of first values over a time window, the determination of the first datum (Esol) comprising the determination of the average of the first values over the time window, the method further comprising the determination of second values, the determination of the second datum (Eutil) comprising the determination of the average of the second values over the time window.
    [11" id="c-fr-0011]
    11. The method of claim 10, wherein the duration of the time window in the first mode of operation is different from the duration of the time window in the second mode of operation.
    B15496 - DD17372MR
    [12" id="c-fr-0012]
    12. The method of claim 10 or 11, wherein the duration of the time window is changed after a period of operation of the battery (14).
    [13" id="c-fr-0013]
    13. The method of claim 1, comprising switching from the first operating mode to the second operating mode when the temperature of the battery (14) is higher than a first temperature value for a determined period.
    [14" id="c-fr-0014]
    14. The method of claim 13, comprising switching from the second operating mode to the first operating mode when the temperature of the battery (14) is lower, for a determined period, to the first temperature value or to a second value of temperature different from the first temperature value.
    [15" id="c-fr-0015]
    15. The method of claim 13 or 14, wherein the battery (14) is charged to a third maximum charge state strictly lower than the second maximum charge state in a third operating mode, the method comprising passing from the second mode of operation in the third operating mode when the temperature of the battery is greater, for a determined period, than a third temperature value strictly greater than the first temperature value.
    [16" id="c-fr-0016]
    16. The method of claim 15, comprising changing from the third operating mode to the second operating mode when the temperature of the battery (14) is lower, for a determined period, to the third temperature value or to a fourth value of temperature, different from the third temperature value and strictly higher than the first temperature value.
    [17" id="c-fr-0017]
    17. Method according to any one of claims 1 to 16, further comprising determining the state of health of the battery (14) and maintaining the state of charge of the battery at the first state of maximum charge when the state of health decreases below a state of health value.
    B15496 - DD17372MR
    [18" id="c-fr-0018]
    18. Method according to any one of claims 1 to 17, in which the charging of the battery (14) is, moreover, prohibited as long as the temperature of the battery is greater than a fifth temperature value.
    [19" id="c-fr-0019]
    19. Method according to any one of claims 1 to 18, in which the charging of the battery (14) is, moreover, prohibited as long as the temperature of the battery is lower than a sixth temperature value.
    [20" id="c-fr-0020]
    20. System (10) comprising an electric generator (16), a battery (14), a circuit (18) for charging the battery from the electric energy supplied by the generator and a module (20) for controlling the charging circuit, the control module being adapted to control the charging of the battery to a first maximum charge state in a first operating mode and to a second maximum charge state, strictly lower than the first maximum charge state, in a second operating mode, the control module being adapted to pass from the second operating mode to the first operating mode when a criterion using the temperature of the battery (14) or the ratio between a first datum (Esol) representative of the available energy that can be supplied by the electric generator and a second datum (Eutil) representative of the energy consumed from the battery is filled.
    [21" id="c-fr-0021]
    21. The system of claim 20, wherein the control module (20) is adapted to pass from the second operating mode to the first operating mode when the ratio between the first datum (Esol) representative of the available energy that can be supplied by the electric generator and the second datum (Eutil) representative of the energy consumed from the battery becomes less than a first threshold.
    [22" id="c-fr-0022]
    22. The system as claimed in claim 21, in which the control module (20) is adapted to pass from the first operating mode to the second operating mode when the ratio between the first datum (Esol) representative of
    B15496 - DD17372MR the available energy that can be supplied by the electric generator and the second data (Eutil) representative of the energy consumed from the battery becomes greater than the first threshold or a second threshold different from the first threshold.
    [23" id="c-fr-0023]
    23. The system of claim 21 or 22, wherein the control module (20) is adapted to control the charge of the battery (14) at a third maximum charge state strictly lower than the second maximum charge state in a third mode. of operation and in which the control module is adapted to pass from the third operating mode to the second operating mode when the ratio between the first datum and the second datum becomes less than a second threshold strictly above the first threshold.
    [24" id="c-fr-0024]
    24. The system of claim 23, wherein the control module (20) is adapted to pass from the second operating mode to the third operating mode when the ratio between the first data and the second data becomes greater than the third threshold, or a fourth threshold different from the third threshold and strictly higher than the first threshold.
    [25" id="c-fr-0025]
    25. The system of claim 20, wherein the control module (20) is adapted to pass from the first operating mode to the second operating mode when the temperature of the battery (14) is greater than a first temperature value during a determined time.
    [26" id="c-fr-0026]
    26. The system of claim 25, wherein the control module (20) is adapted to pass from the second operating mode to the first operating mode when the temperature of the battery (14) is lower, for a determined period, to the first temperature value or at a second temperature value, different from the first temperature value.
    [27" id="c-fr-0027]
    27. The system of claim 25 or 26, wherein the control module (20) is adapted to control the charge of the battery (14) at a third maximum charge state strictly lower than the second maximum charge state in a third
    B15496 - DD17372MR operating mode, and in which the control module is adapted to pass from the second operating mode to the third operating mode when the temperature of the battery is higher, for a determined period, at a third value
    5 of temperature strictly higher than the first temperature value.
    [28" id="c-fr-0028]
    28. The system of claim 27, wherein the control module is adapted to pass from the third operating mode to the second operating mode when the
    The temperature of the battery (14) is lower, for a determined period, to the third temperature value or to a fourth temperature value different from the third temperature value and strictly higher than the first temperature value.
    15
    [0029]
    29. System according to any one of claims 20 to 28, in which the electric generator (16) comprises photovoltaic cells.
    B15496
    1/5 ίο.
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    CN111092463A|2018-10-23|2020-05-01|丰田自动车株式会社|Secondary battery system and charging control method for secondary battery|
    EP3828374A1|2019-11-28|2021-06-02|Nien Made Enterprise Co., Ltd.|Charging system for electric window covering|
    法律状态:
    2018-01-02| PLFP| Fee payment|Year of fee payment: 2 |
    2018-06-22| PLSC| Publication of the preliminary search report|Effective date: 20180622 |
    2018-11-09| RM| Correction of a material error|Effective date: 20181008 |
    2019-12-31| PLFP| Fee payment|Year of fee payment: 4 |
    2020-12-28| PLFP| Fee payment|Year of fee payment: 5 |
    2021-12-31| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1662966A|FR3060889B1|2016-12-21|2016-12-21|METHOD AND DEVICE FOR CHARGING A BATTERY|
    FR1662966|2016-12-21|FR1662966A| FR3060889B1|2016-12-21|2016-12-21|METHOD AND DEVICE FOR CHARGING A BATTERY|
    EP17207861.0A| EP3340428A3|2016-12-21|2017-12-15|Method and device for charging a battery|
    US15/848,222| US11251648B2|2016-12-21|2017-12-20|Battery charge method and device|
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