WO2023061810A1 - Power supply device, e-cigarette, and method for generating electric power - Google Patents

Abstract

The invention relates to a power supply device (3) for an e-cigarette (1), having at least two power supply units (5, 6), which each have a rechargeable battery (7), the one set of like electrical terminals (8) of the rechargeable batteries (7) being connected to one another. In order to provide an improved power control concept for an e-cigarette (1), the power supply device (3) has at least one control arrangement (9) which is designed to divide a target power (PSoll), to be generated by the power supply device (3), individually among the individual power supply units (5,6), taking into account, on the one hand, the actual partial powers (PIst,1, PIst,2) of the individual power supply units (5, 6) and/or, on the other hand, actual partial currents (IIst,1, IIst,2) of the individual power supply units (5, 6) and a voltage drop caused by an electrical load (2) connectable or connected to the power supply device (3).

Description

Energy supply device, e-cigarette and method for generating electrical power

technical field

The invention relates to an energy supply device for an e-cigarette, having at least two energy supply units, each of which has a secondary battery, with the electrical poles of the secondary batteries having the same name being connected to one another. In addition, the invention relates to an e-cigarette with at least one electrical load and at least one energy supply device for supplying the electrical load with electrical energy. The invention also relates to a method for generating electrical power for operating an electrical load of an e-cigarette, the power being generated using at least two energy supply units, each having a secondary battery, with one electrical pole of the secondary battery having the same name connected to one another are connected.

State of the art

In order to increase the vaporization performance of modern e-cigarettes, control electronics are built into e-cigarettes, which are capable of delivering more power to a heating coil of an e-cigarette vaporizer than is provided by a single secondary battery, also called an accumulator, of the e-cigarette can be. Basically, a series connection as well as a parallel connection of individual secondary batteries of an e-cigarette is possible.

With a conventional parallel connection of secondary batteries of an e-cigarette, however, there is the problem that in the case of two or more secondary batteries with different states of charge, strong equalizing currents flow, via which a more heavily charged secondary battery charges a less heavily charged secondary battery. Since the internal resistance of a secondary battery should be as small as possible, relatively strong compensating currents arise even with very small voltage differences between the output voltages of secondary batteries connected in parallel. For this reason, a series connection, also called series connection, which uses secondary batteries is preferred in some e-cigarettes. With the series connection, all secondary batteries are connected in series, whereby the individual output voltages of the secondary batteries are added, while the same current flows through all secondary batteries. However, this means that secondary batteries that have a higher internal resistance, for example secondary batteries with a longer service life, as the weakest link in the chain formed by the secondary batteries, can become too hot.

In addition, when charging secondary batteries connected in series, care must be taken to ensure that the secondary batteries can have different states of charge and are therefore fully charged at different rates. Complex balance circuits must therefore be installed in order to prevent a secondary battery in a series circuit that is already fully charged from continuing to be supplied with electrical energy while another secondary battery in the series circuit is still being charged.

Finally, a series connection of secondary batteries also places special demands on the mechanical construction of an e-cigarette. While the negative poles of all secondary batteries are usually connected together when secondary batteries are connected in parallel and this electrical potential is then referred to as ground, with series connection the negative pole of the first secondary battery is connected to ground and the negative pole of the second secondary battery is connected to the positive pole of the first secondary battery , and, if more than two secondary batteries are used, the negative terminal of the third secondary battery with the positive terminal of the second secondary battery, etc. The positive terminal of the last secondary battery in the series connection then serves as the electrical contact for the power supply.

All other electrical intermediate potentials of the series connection must still be tapped so that the discharge state of each individual secondary battery can be detected and in order to be able to implement the balancing required during charging using a balance circuit. However, these electrical intermediate potentials must under no circumstances come into contact with a housing of the e-cigarette, which in the form of a metal housing usually has the electrical ground potential, since otherwise all secondary batteries from this contact point to the first secondary battery would be short-circuited. Since conventional secondary batteries usually have a metal can, which forms the negative pole of the secondary battery, which is electrically insulated on the outside only by means of a shrink film applied to it, there is a great risk of a short circuit, since the shrink film can be damaged very easily and the metal can thus come into electrical contact can come with the body of the e-cigarette. For this reason, solid metallic constructions of series-connected secondary batteries of an e-cigarette should always have an additional insulating body that prevents the said short circuit from occurring.

DE 10 2017 121 664 A1, EP 3 701 815 A1, EP 3 701 819 A1, EP 3 701 820 A1, EP 3 744 195 A1, US 9 894 938 B2, WO 2019/171 297 A1, WO 2020/117 A11 and WO 2020 / 064 347 A1 disclose various configurations of e-cigarettes.

Disclosure of Invention

One object of the invention is to provide an improved power control concept for an e-cigarette of the type mentioned at the outset.

This object is solved by the independent patent claims. Advantageous configurations are given in the dependent patent claims, the following description and the figures, wherein these configurations, taken individually or in combination with at least two of these configurations, can represent an advantageous and/or further developing aspect of the invention. Advantageous configurations of the energy supply device can correspond to advantageous configurations of the method and vice versa, even if this is not explicitly pointed out below.

An energy supply device according to the invention for an e-cigarette has at least two energy supply units, each of which has a secondary battery, with the electrical poles of the secondary batteries having the same name being connected to one another. In addition, the energy supply device according to the invention has at least one control arrangement that is set up to calculate a target power to be generated by the energy supply device, taking into account actual partial powers of the individual energy supply units on the one hand and/or actual partial currents of the individual energy supply units and a Power supply device connectable or connected electrical On the other hand, the voltage drop caused by the load can be divided individually between the individual power supply units.

According to the invention, a new power control concept for supplying an electrical load, in particular an evaporator, of an e-cigarette with electrical energy is proposed, in which, similar to a parallel connection of secondary batteries, all secondary batteries are electrically connected to one of the electrical poles of the same name, preferably their negative poles are connected to each other. This electrical potential can be referred to as ground. Since the individual secondary batteries can have different states of charge or charging voltages, the other poles of the same name (opposite poles) of the secondary batteries are not electrically connected to one another, since otherwise strong compensating currents would occur, as explained above with regard to the prior art. Instead, according to the invention, the control arrangement is present, which is set up to generate a total target power to be generated by the energy supply device in each case, taking into account actual partial powers of the individual energy supply units on the one hand and/or actual partial currents of the individual energy supply units and a connection that can be connected to the energy supply device or connected electrical load caused voltage drop, in particular in an output voltage of the energy supply device, on the other hand individually to the individual energy supply units. This makes it possible to electrically connect the outputs of the energy supply units, which are electrically connected to the other poles of the same name, for example the positive poles, of the secondary batteries, without compensating currents occurring.

The total target power to be generated by the energy supply device preferably serves to supply power to an evaporator of an e-cigarette equipped with the energy supply device according to the invention, in particular during a vaporization process or sublimation process carried out by the e-cigarette.

The actual partial powers of the individual energy supply units can be measured using power measuring units. The actual partial currents of the individual energy supply units can be measured using current measuring units. The through the connectable or connected to the power supply device electrical Load-caused voltage drop in the output voltage of the power supply device can be measured by a voltage measuring unit. The electrical load can be formed by the evaporator or a heating unit of the same.

The control arrangement can have at least one microcontroller, which receives as input variables the total target power to be generated by the energy supply device and the actual partial powers of the individual energy supply units on the one hand and/or the actual partial currents of the individual energy supply units and the connected electric load caused voltage drop in an output voltage of the power supply device on the other hand. An algorithm can be implemented with the microcontroller in order to be able to distribute the target power individually to the individual energy supply units, taking into account the respective input variables. The control arrangement can be designed as a digital controller.

The energy supply device according to the invention can also have more than two energy supply units, each of which has a secondary battery, wherein the electrical poles of the same name, in particular all of the secondary batteries, are connected to one another. Each power supply unit may include at least one electronic component in addition to a single secondary battery. The energy supply units can be of the same design. The control arrangement can be an assembly that is separate from the energy supply units or can be partially formed by components of the energy supply units.

The output currents of the energy supply units flow together at a point where an output voltage of the energy supply device then forms, which is the same for all energy supply units. This confluence of the currents of the energy supply units also means that the outputs of the energy supply units are added.

According to an advantageous embodiment, the control arrangement is set up to distribute the target power individually to the individual energy supply units, also taking into account battery voltages of the individual secondary batteries, in such a way that a secondary battery with a higher battery voltage generates a larger proportion of the target power than a secondary battery with a lower one battery voltage. Accordingly, a secondary battery with a higher state of charge is more heavily loaded than a secondary battery with a lower state of charge. The internal resistance of a secondary battery usually increases over the course of its use, so that, according to this embodiment, younger secondary batteries are also more heavily loaded than older secondary batteries. The battery voltages of the individual secondary batteries can either be measured separately using voltage measuring units or fed directly to the control arrangement as input variables.

According to a further advantageous embodiment, each energy supply unit has at least one DC voltage converter which is connected downstream of the secondary battery of this energy supply unit and can be regulated with the control arrangement. Since the output voltage of the respective secondary battery can be increased, reduced or kept the same with the respective DC-DC converter, depending on the situation, the DC-DC converter is designed both as a step-up converter and as a step-down converter and can therefore be referred to as a step-up and step-down converter. The DC-DC converters can be controlled by the control arrangement in such a way that the output powers and/or the output currents of the individual energy supply units can be varied in order to be able to distribute the target power to be generated by the energy supply device individually to the individual energy supply units. The assembly formed from the respective secondary battery and the respective DC voltage converter can also be referred to as a controllable current source. If the value of a manipulated variable of the respective DC-DC converter is increased when the electrical load is connected, the output current and thus the output power of the respective energy supply unit also increase.

The DC-DC converter can be designed, for example, as a cascaded step-down and step-up converter (buck-boost converter), which has a series connection with a step-down converter, a step-up converter and a storage inductor. Alternatively, the DC/DC converter can be in the form of a SEPIC converter, which is also a step-down and step-up converter. The diode of the SEPIC converter can be replaced by another controllable switch to increase efficiency. Alternatively, the DC-DC converter can be in the form of an inverse converter. The inverse converter is also a buck and boost converter, but it converts a positive input voltage into a negative output voltage, which reverses the direction of the current. However, this is not relevant for the operation of an e-cigarette. The diode in Inverse converter can be replaced by a second synchronously controllable switch to increase efficiency. In general, any type of converter can be used as a DC converter whose output voltage is in a range from 0 V to above the applied input voltage.

According to a further advantageous embodiment, the control arrangement is set up to determine the actual partial power or the actual partial current of the respective energy supply unit, the control arrangement being set up to generate an individual target partial power signal or an individual target partial current signal for each energy supply unit and to regulate the DC-DC converter of the respective energy supply unit depending on a deviation of the actual partial power of this energy supply unit from the target partial power signal assigned to this energy supply unit and/or depending on a deviation of the actual partial current of this energy supply unit from the target partial current signal assigned to this energy supply unit. The respective individual target partial power signal or the respective individual target partial current signal can be generated by the control arrangement, for example, taking into account the target power to be generated by the energy supply device and the actual partial power or the actual partial current of the respective energy supply unit. A corresponding electrical signal can be generated for the respective deviation, which can be fed to the respective DC-DC converter as a manipulated variable in order to regulate the DC-DC converter. The respective individual actual partial power can be determined, for example, by multiplying the respective individual actual partial current by the output voltage common to the energy supply units.

According to a further advantageous embodiment, the control arrangement is set up to generate the individual target partial power signals or target partial current signals in such a way that the target power is divided individually between the individual energy supply units in such a way that each secondary battery has the same discharge state when continuously loaded with this power distribution reached. For this purpose, a secondary battery with a higher state of charge is more heavily loaded than a secondary battery with a lower state of charge.

According to a further advantageous refinement, the control arrangement is set up to use the individual target partial power signals and/or the individual target partial current To generate signals in such a way that the energy supply device generates a maximum power that is a sum of the maximum possible powers of the individual secondary batteries, or to generate the individual target partial power signals and/or the individual target partial current signals in such a way that a permissible maximum current intensity of the single secondary battery is not exceeded. This reliably prevents individual secondary batteries from being overloaded, which is particularly important in the event that the desired power required or to be generated by the energy supply device is higher than the sum of the possible maximum powers of the individual secondary batteries.

According to a further advantageous embodiment, the control arrangement for each energy supply unit has on the one hand at least one separate power detection unit connected in series with the DC-DC converter for detecting the actual partial power and/or on the other hand at least one separate current detection unit connected in series with the DC-DC converter for detecting the actual partial current and at least a voltage detection unit that can be connected in parallel with the electrical load to detect the voltage drop. The respective power detection unit or current detection unit can be installed in the respective energy supply unit.

According to a further advantageous embodiment, the control arrangement has on the one hand for each energy supply unit at least one dedicated power controller connected to the DC-DC converter and/or at least one dedicated current controller connected to the DC-DC converter and on the other hand at least one higher-level ratio controller connected to the power controllers or current controllers. The respective power controller or current controller can be installed in the respective energy supply unit, while the ratio controller can be arranged outside of the energy supply units. The respective power controller or current controller can output a manipulated variable for controlling the respective DC-DC converter. For this purpose, the ratio controller can supply the respective power controller or current controller with the associated desired partial power signal or desired partial current signal, which the ratio controller has previously determined. The ratio controller is set up to divide the target power to be generated by the energy supply device between the individual energy supply units as described above. Alternatively, the Ratio controller and the power controller or current controller can be realized by a single unit.

The ratio controller can request the same power from each power supply unit regardless of the battery voltages of the secondary batteries, as long as the secondary batteries can supply that power, simply according to the principle "required power = power of each power supply unit * number of power supply units" or according to the principle "requested Output of an energy supply unit = requested total output / number of energy supply units" and, if a secondary battery can no longer supply the power requested by it, the requested power required by the energy supply device should be divided among the other secondary batteries in such a way that they generate power overall , which is less than the target performance. (Control concept 1). However, this control concept only takes into account the different capacities of the individual secondary batteries to a limited extent.

The ratio controller is therefore set up to divide the target power to be generated by the energy supply device, taking into account the measured instantaneous battery voltages of the secondary batteries, individually among the energy supply units in such a way that the energy supply unit with a secondary battery that has a higher voltage delivers a higher partial power than an energy supply unit , whose secondary battery has a lower voltage (control concept 2).

For example, Psoii.i can apply to the target partial power to be provided by the respective energy supply unit i

as long as Ui > Uo, otherwise Psoii.i = 0. If Psoii.i is higher than the maximum allowed power of a power supply unit, Psoiu can be set to the maximum allowed power of the power supply unit. P _SO II is the target power to be generated by the energy supply device, Ui is the current battery voltage of the secondary battery of the respective energy supply unit i, n is the number of existing energy supply units i whose respective voltage is >Uo, and Uo is one Reference voltage above which the respective energy supply unit should no longer deliver any power. In this case, the entire energy supply device can be switched off before the battery voltage of a secondary battery is below the reference voltage Uo. Alternatively, the power supply unit whose secondary battery has a battery voltage that falls below the reference voltage Uo cannot be used by the ratio controller to generate the target power, so that the target power is only generated using the other power supply units or the secondary battery , whose battery voltage falls below the reference voltage Uo, is not taken into account in the above equation.

By taking into account the instantaneous battery voltage of the respective secondary battery, not only the state of charge of this secondary battery but also the internal resistance of this secondary battery and thus the possible performance of this secondary battery are included in the regulation. The internal resistance of the respective secondary battery is also included in the regulation, since a voltage drops across it when current flows and the battery voltage present at the electrical poles of the secondary battery thus collapses or decreases.

In addition, the ratio controller can be set up to generate the individual target partial power signals in such a way that the target power to be generated by the energy supply device corresponds to the battery voltage of the respective secondary batteries before the start of a vapor process or sublimation process that can be carried out with a correspondingly equipped e-cigarette is distributed individually to the energy supply units (control concept 3).

The ratio controller can also be set up to generate the target partial power signals in such a way that the target power is first divided into three identical or different power values, the sum of which results in the target power. The ratio controller can be set up to split the first power value according to control concept 1, the second power value according to control concept 2 and the third power value according to control concept 3 individually to the individual energy supply units.

An e-cigarette according to the invention has at least one electrical load and at least one energy supply device for supplying the electrical load electrical energy, wherein the energy supply device is designed according to one of the above configurations or a combination of at least two of these configurations with one another.

The advantages mentioned above in relation to the energy supply device are correspondingly associated with the e-cigarette. The e-cigarette can essentially be modeled on a classic cigarette or be designed in a completely different way. An e-cigarette should therefore be understood to mean any device with which a liquid can be vaporized or a solid can be sublimated with the supply of heat in order to be able to inhale the resulting vapor. The electrical load can be designed as an evaporator with at least one heating coil, which can be supplied with electrical power by means of the energy supply device.

According to a method according to the invention for generating electrical power for operating an electrical load of an e-cigarette, the power is generated using at least two energy supply units, each having a secondary battery, with one electrical pole of the secondary battery having the same name being connected to one another and one the target power to be generated by the energy supply device, taking into account actual partial outputs of the individual energy supply units on the one hand and/or actual partial currents of the individual energy supply units and a voltage drop caused by an electrical load that can be connected or is connected to the energy supply device on the other hand divided individually among the individual energy supply units .

The advantages mentioned above in relation to the energy supply device are correspondingly associated with the method. In particular, the energy supply device can be used according to one of the above-mentioned configurations or a combination of at least two of these configurations with one another to carry out the method.

According to an advantageous embodiment, the target power is distributed individually to the individual energy supply units, also taking into account battery voltages of the individual secondary batteries, such that a secondary battery with a higher battery voltage has a larger proportion of the target power generated than a secondary battery with a lower battery voltage. The advantages mentioned above in relation to the corresponding configuration of the energy supply device are correspondingly associated with this configuration.

According to a further advantageous embodiment, an individual target partial power signal or an individual target partial current signal is generated for each energy supply unit and a secondary battery of the respective energy supply unit downstream DC-DC converter of this energy supply unit depending on a deviation of the actual partial power of this energy supply unit from the target assigned to this energy supply unit. Partial power signal and/or controlled as a function of a deviation of the actual partial current of this energy supply unit from the setpoint partial current signal assigned to this energy supply unit. The advantages mentioned above in relation to the corresponding configuration of the energy supply device are correspondingly associated with this configuration.

According to a further advantageous embodiment, the individual target partial power signals or the individual target partial current signals are generated in such a way that the target power is divided individually between the individual energy supply units such that each secondary battery reaches the same discharge state under continuous load with this power distribution . The advantages mentioned above in relation to the corresponding configuration of the energy supply device are correspondingly associated with this configuration.

According to a further advantageous embodiment, the individual target partial power signals and/or the individual target partial current signals are generated in such a way that the power supply device generates a maximum power that is a sum of the maximum possible powers of the individual secondary batteries or the individual To generate target partial power signals and/or the individual target partial current signals in such a way that a permissible maximum current of the individual secondary battery is not exceeded.

In the following, the invention is explained by way of example with reference to the accompanying figures using preferred embodiments, with the features explained below both taken individually and in different combinations together can represent an advantageous and/or further developing aspect of the invention.

Brief description of the figures

Show it:

1 shows a block diagram of an exemplary embodiment of an e-cigarette according to the invention;

2 shows a block diagram of a further exemplary embodiment of an e-cigarette according to the invention; and

3 shows a block diagram of a further exemplary embodiment of an e-cigarette according to the invention.

Detailed description of the figures

Identical or functionally identical components are provided with the same reference symbols in the figures. Repeated description of such components in detail may be omitted to avoid unnecessary repetition.

1 shows a block diagram of an exemplary embodiment of an e-cigarette 1 according to the invention with an electrical load 2 in the form of an evaporator and an energy supply device 3 for supplying the electrical load 2 with electrical energy.

The electrical load 2 has a heating coil 4 which can be energized and which is electrically connected on the one hand to an electrical ground (not shown) of the energy supply device 3 and on the other hand to the energy supply device 3 .

The energy supply device 3 has two identically designed energy supply units 5 and 6, each of which has a secondary battery 7, with the electrical poles 8 of the secondary batteries 7 having the same name, namely their negative poles, being electrically connected to one another via the electrical ground of the energy supply device 3. In addition, the energy supply device 3 has a control arrangement 9, which is set up to generate a target power Psou to be generated by the energy supply device 3, taking into account actual partial power Pi _s t,i and Pi _s t,2 of the individual energy supply units 5 and 6 split individually on the individual power supply units 5 and 6.

The control arrangement 9 is set up to distribute the target power P _SO II individually to the individual energy supply units 5 and 6, also taking into account the battery voltages VBI and VB2 of the individual secondary batteries 7, in such a way that a secondary battery 7 with a higher battery voltage VBI or VB2 generates a larger proportion of the target power P _SO II than a secondary battery 7 with a lower battery voltage VBI or VB2.

Each power supply unit 5 or 6 has a secondary battery 7 of this power supply unit 5 or 6 downstream of a DC voltage converter 10 that can be controlled with the control arrangement 9 .

The control arrangement 9 is set up to determine the actual partial power Pi _s t,i and Pi _s t,2 of the respective energy supply unit 5 or 6 . For this purpose, the control arrangement 9 has a separate power detection unit 11 for each energy supply unit 5 or 6, which is connected in series with the DC-DC converter 10 of the respective energy supply unit 5 or 6 and thus forms part of the respective energy supply unit 5 or 6.

In addition, the control arrangement 9 has for each energy supply unit 5 or 6 its own power controller 13 connected to the DC-DC converter 10 and a higher-level ratio controller 14 connected to the power controllers 13 . The respective power controller 13 also forms part of the respective energy supply unit 5 or 6.

Furthermore, the control arrangement 9 or its ratio controller 14 is set up to generate an individual target partial power signal P _SOII ,I or Psoii,2 for each energy supply unit 5 or 6, respectively. In addition, the control arrangement 9 is set up to switch the DC-DC converter 10 of the respective energy supply unit 5 or 6 as a function of a deviation of the actual partial power Pi _s t,i or Pi _s t,2 of this energy supply unit 5 or 6 from that of this energy supply unit 5 or 6 assigned target To regulate partial power signal Psoii.i or Psoii.2. For this purpose, the ratio controller 14 supplies the power controllers 13 with the target partial power signal P _SO II,I or Psoii,2, which then, depending on the deviation or difference Psoii.i - Pist.i or Psoii,2 - Pist,2 die determine the respective values for manipulated variables S1 and S2, which are then fed to the DC-DC converters 10 in order to regulate them.

The control arrangement 9 is set up to generate the individual target partial power signals Psoii.i and Psoii,2 in such a way that the target power P _SO II is distributed individually to the individual energy supply units 5 and 6 in such a way that each secondary battery 7 with continuous load this power distribution reaches the same state of discharge.

Furthermore, the control arrangement 9 is set up to generate the individual target partial power signals Psoii.i and Psoii,2 in such a way that the energy supply device 3 generates a maximum power that is a sum of the maximum possible powers of the individual secondary batteries 7 .

2 shows a block diagram of a further exemplary embodiment of an e-cigarette 15 according to the invention with an electrical load 2 in the form of an evaporator and an energy supply device 16 for supplying the electrical load 2 with electrical energy.

The electrical load 2 has a heating coil 4 which can be energized and which is electrically connected on the one hand to an electrical ground (not shown) of the energy supply device 16 and on the other hand to the energy supply device 16 .

The energy supply device 16 has two identically designed energy supply units 17 and 18, each of which has a secondary battery 7, with the electrical poles 8 of the secondary batteries 7 having the same name, namely their negative poles, being electrically connected to one another via the electrical ground of the energy supply device 3.

In addition, the energy supply device 16 has a control arrangement 19, which is set up to generate a target power P _SO II to be generated by the energy supply device 16, taking into account actual partial currents h _s t,i and h _s t,2 of the individual energy supply units 17 and 18 and one through the with the Power supply device 16 connected electrical load 2 caused voltage drop Uiast split individually on the individual power supply units 17 and 18.

The control arrangement 19 is set up to distribute the target power P _SO II individually to the individual energy supply units 17 and 18, also taking into account the battery voltages VBI and VB2 of the individual secondary batteries 7, in such a way that a secondary battery 7 with a higher battery voltage VBI or VB2 generates a larger proportion of the target power P _SO II than a secondary battery 7 with a lower battery voltage VBI or VB2.

Each energy supply unit 17 or 18 has a secondary battery 7 of this energy supply unit 17 or 18 downstream and can be regulated with the regulating arrangement 19 DC-DC converter 10 .

The control arrangement 19 is set up to determine the actual partial current h _s t,i or h _s t,2 of the respective energy supply unit 17 or 18 . For this purpose, the control arrangement 19 for each power supply unit 17 or 18 has its own current detection unit 20 connected in series with the DC-DC converter 10 for detecting the actual partial current hst,i or h _s t,2 and one connected in parallel with the electrical load 2 Voltage detection unit 21 for detecting the voltage drop Uiast.

In addition, the control arrangement 19 has for each energy supply unit 17 or 18 its own current controller 22 connected to the DC-DC converter 10 and a higher-level ratio controller 23 connected to the current controllers 22 . The respective current governor 22 also forms part of the respective energy supply unit 17 or 18.

Furthermore, the control arrangement 19 or its ratio controller 23 is set up to generate an individual setpoint partial current signal I _SO II,I or Isoii,2 for each energy supply unit 17 or 18, respectively. In addition, the control arrangement 19 is set up to switch the DC-DC converter 10 of the respective energy supply unit 17 or 18 as a function of a deviation of the actual partial current h _s t,i or h _s t,2 of this energy supply unit 17 or 18 from that of this energy supply unit 17 or 18 associated nominal partial current signal I _SO II,I or I _SO II,2 to regulate. For this purpose, the ratio controller 23 leads to the current controllers 22, the target partial current signals I _SO II, I and l _So ii, 2, which then depend on the Deviation or difference I _SO II,I - hst,i or Isoii,2 - hst,2 determine the respective values for manipulated variables S1 and S2, which are then fed to the DC-DC converters 10 in order to regulate them.

The control arrangement 19 is set up to generate the individual target partial current signals I _SO II,I and lsoii,2 in such a way that the target power P _S oii is distributed individually to the individual energy supply units 17 and 18 in such a way that each secondary battery 7 continuous load with this power distribution reaches the same state of discharge.

Furthermore, the control arrangement 19 is set up to generate the individual setpoint partial current signals lsoii,i and lsoii,2 in such a way that the energy supply device 15 generates a maximum power that is a sum of the maximum possible powers of the individual secondary batteries 7, or the to generate individual target partial current signals I _SO II,I and lsoii,2 in such a way that a permissible maximum current intensity of the individual secondary battery 7 is not exceeded.

Fig. 3 shows a block diagram of a further exemplary embodiment of an e-cigarette 24 according to the invention.

The e-cigarette 24 differs from the exemplary embodiment shown in FIG. 2 in that instead of the separate current controller (FIG. 2) and the ratio controller (FIG. 2), there is a control arrangement 25 in the form of a power controller that performs the tasks of the current controller and the ratio controller takes over.

In order to avoid repetition, reference is also made to the above description of FIG.

Reference List

1 e-cigarette

2 electrical load

3 power supply device

4 heating coils from 2

5 power supply unit

6 power supply unit

7 secondary battery

8 electrical pole (negative pole) of 7

9 rule arrangement

10 adjustable DC-DC converters

11 power acquisition unit

13 power controls

14 ratio controller

15 e-cigarette

16 power supply device

17 power supply unit

18 power supply unit

19 rule arrangement

20 current detection unit

21 voltage detection unit

22 electricity govern

23 ratio controller

24 e-cigarette

25 control arrangement hst,i actual partial current hst, 2 actual partial current lsoii,i desired partial current signal lsoii,2 desired partial current signal

Pist,i Actual partial power

Pist,2 Actual partial power

Psou target power

Psoii,i target partial power signal Psoii,2 target partial power signal

51 control variable

52 control variable

VBI battery voltage

VB2 battery voltage

Uiast voltage drop

Claims

Claims Energy supply device (3, 16) for an e-cigarette (1, 15, 24), having at least two energy supply units (5, 6, 17, 18), each having a secondary battery (7), wherein the one electrical pole ( 8) the secondary batteries (7) are connected to one another, characterized by at least one control arrangement (9, 19, 25) which is set up to generate a target power (Psou) to be generated in each case by the energy supply device (3, 16), taking into account actual - Partial outputs (Pist.i, Pist,2) of the individual energy supply units (5, 6, 17, 18) on the one hand and/or actual partial currents (hst.i, hst,2) of the individual energy supply units (5, 6, 17, 18) and a voltage drop (Ui_ast) caused by an electrical load (2) that can be connected or is connected to the energy supply device (3, 16), on the other hand, individually to the individual energy supply units (5, 6, 17, 18). Energy supply device (3, 16) according to Claim 1, characterized in that the control arrangement (9, 19, 25) is set up to calculate the target power (P _SO II ) with additional consideration of battery voltages (VBI , VB2) of the individual secondary batteries (7th ) distributed individually to the individual energy supply units (5, 6, 17, 18) such that a secondary battery (7) with a higher battery voltage (VBI, VB2) generates a larger proportion of the target power (P _SO II) than a secondary battery ( 7) with a lower battery voltage (VBI , VB2). Energy supply device (3, 16) according to claim 1 or 2, characterized in that each energy supply unit (5, 6, 17, 18) at least one of the secondary battery (7) downstream of this energy supply unit (5, 6, 17, 18) with the control arrangement (9, 19, 25) controllable DC-DC converter (10). Energy supply device (3, 16) according to one of Claims 1 to 3, characterized in that the control arrangement (9, 19, 25) is set up to control the actual partial power (Pactual,i, Pactual,2) or the actual partial current ( hst.i, hst,2) of the respective energy supply unit (5, 6, 17, 18) to be determined, the control arrangement (9, 19, 25) being set up for each energy supply unit (5, 6, 17, 18) an individual Target partial power signal (Psoii.1, Psoii,2) or an individual target partial current signal (Isoii.i, lsoii,2) and the DC-DC converter (10) of the respective energy supply unit (5, 6, 17, 18) depending on a deviation of the actual partial power (Pist.i, Pist,2) of this energy supply unit (5, 6, 17, 18) from the setpoint partial power signal (Psoii,i, Psoii,2) assigned to this energy supply unit (5, 6, 17, 18) and/or depending on a deviation of the actual partial current (hst.i , hst,2) from this energy supply unit (5, 6, 17, 18) by the setpoint partial current signal (I _SO II,I, Isoii,2> assigned to this energy supply unit (5, 6, 17, 18).

5. Energy supply device (3, 16) according to claim 4, characterized in that the control arrangement (9, 19, 25) is set up, the individual target partial performance signals (Psoii.i, Psoii,2) and / or the individual target -To generate partial current signals (Isoii.i, lsoii,2) in such a way that the target power (P _SO II) is distributed individually to the individual energy supply units (5, 6, 17, 18) in such a way that each secondary battery (7) at continuous load with this power distribution reaches the same state of discharge.

6. Energy supply device (3, 16) according to claim 4 or 5, characterized in that the control arrangement (9, 19, 25) is set up, the individual target partial power signals (Psoii.i, Psoii,2) or the individual target To generate partial current signals (I _SO II, I, lsoii, 2) in such a way that the power supply device (3, 16) generates a maximum power that is a sum of the maximum possible powers of the individual secondary batteries (7), or the individual To generate target partial power signals (Psoii.i, Psoii,2) and/or the individual target partial current signals (Isoii.i, lsoii,2) in such a way that a permissible maximum current of the individual secondary battery (7) is not exceeded.

7. Energy supply device (3, 16) according to one of claims 3 to 6, characterized in that the control arrangement (9, 19, 25) for each energy supply unit (5, 6, 17, 18) on the one hand at least one in series with the DC voltage converter ( 10) connected dedicated power detection unit (11) for detecting the actual partial power (Pist.i , Pactual,2) and/or on the other hand at least one dedicated current detection unit (20) connected in series with the DC-DC converter (10) for detecting the actual partial current ( hst.i , hst,2) and at least one voltage detection unit (21) which can be switched or is connected in parallel with the electrical load (2) for detecting the voltage drop (Ui_ast). 8. Energy supply device (3, 16) according to one of Claims 3 to 7, characterized in that the control arrangement (9, 19) has on the one hand for each energy supply unit (5, 6, 17, 18) at least one dedicated power controller (13) and/or at least one dedicated current controller (22) connected to the DC-DC converter (10) and on the other hand at least one higher-level ratio controller (14, 23) connected to the power controllers (13) or current controllers (22).

9. E-cigarette (1, 15, 24) with at least one electrical load (2) and at least one energy supply device (3, 16) for supplying the electrical load (2) with electrical energy, characterized in that the energy supply device (3, 16) according to any one of claims 1 to 8 is formed.

10. A method for generating electrical power for operating an electrical load (2) of an e-cigarette (1), the power being generated using at least two energy supply units (5, 6, 17, 18), each of which has a secondary battery (7th ) have, is generated, wherein the one electrical pole (8) of the secondary batteries (7) of the same name are connected to one another, characterized in that a target power (Psou) to be generated in each case by the energy supply device (3, 16) taking into account actual - Partial outputs (Pist.i, Pist,2) of the individual energy supply units (5, 6, 17, 18) on the one hand and/or actual partial currents (hst.i, hst,2) of the individual energy supply units (5, 6, 17, 18) and a voltage drop (Ui_ast) caused by an electrical load (2) that can be connected or is connected to the energy supply device (3, 16) on the other hand is distributed individually to the individual energy supply units (5, 6, 17, 18).

11 . Method according to Claim 10, characterized in that the target power (P _SO II ) is distributed individually to the individual energy supply units (5, 6, 17, 18) with additional consideration of battery voltages (VBI , VB2) of the individual secondary batteries (7). is that a secondary battery (7) with a higher battery voltage (VBI, VB2) generates a larger proportion of the target power (P _SO II) than a secondary battery (7) with a lower battery voltage (VBI, Vß2). Method according to Claim 10 or 11, characterized in that for each energy supply unit (5, 6, 17, 18) an individual setpoint partial power signal (Psoii.i, Psoii,2) or an individual setpoint partial current signal (Isoii.i, lsoii ,2> is generated and a DC-DC converter (10) connected downstream of the secondary battery (7) of the respective energy supply unit (5, 6, 17, 18) of this energy supply unit (5, 6, 17, 18) as a function of a deviation in the actual partial power (Pact .i, Pactual,2) of this energy supply unit (5, 6, 17, 18) from the target partial power signal (Psoii.i, Psoii,2) assigned to this energy supply unit (5, 6, 17, 18) and/or as a function of a Deviation of the actual partial current (hst,i , hst,2) of this energy supply unit (5, 6, 17, 18) from the target partial current signal (Isoii.i, Isoii. ) assigned to this energy supply unit (5, 6, 17, 18) The method according to claim 12, characterized in that the individual setpoint partial power signals (PSOII.BI, Psoii,B2) or the individual setpoint partial current signals (Isoii.i, lsoii,2) are generated in such a way that the setpoint Power (P _SO II) is divided individually between the individual energy supply units (5, 6, 17, 18) in such a way that each secondary battery (7) reaches the same state of discharge under continuous load with this power distribution. The method according to claim 12 or 13, characterized in that the individual target partial power signals (PSOII.BI, PSOU, B2) and / or the individual target partial current signals (I _SO II, I, Isoii.) Are generated such that the maximum power generated by the energy supply device (3, 16) is the sum of the maximum possible powers of the individual secondary batteries (7), or the individual target partial power signals (PSOII.BI, PSOII,B2) and/or the individual Target part current signals (Isoii.i, Isoii.) To generate such that a maximum permissible current of each secondary battery (7) is not exceeded.