DE102013002289A1 - Battery charging system for internal combustion engine, has loading electronics that part-loads connectable battery with energy from connectable power supply and full-loads battery with energy from residue loading storage portion - Google Patents

Abstract

The battery charging system (10) has an output terminal (12) that is connected to a to-be-charged battery (14). An input terminal (16) is connected to a power supply (18). A loading electronics (20) is used for controlling the charging process and for charging a residue loading storage portion (22) with energy from the connectable power supply. The loading electronics is configured to part-load the connectable battery with energy from the connectable power supply and to full-load the connectable battery with energy from the residue loading storage portion. An independent claim is included for method for charging battery.

Description

The present invention relates to a battery charging system having an output terminal to which a battery to be charged is connectable and an input terminal to which a power source is connectable, wherein the battery charging system comprises a charging electronics for controlling a charging operation.

The present invention further relates to a method of charging a battery connectable to an output terminal of a battery charging system, wherein an energy source is connected to an input terminal of the battery charging system, and the battery is connected to the output terminal.

Battery charging systems use electrical energy provided by a power source that can be coupled to the battery charging system to charge a battery that can be coupled to the battery charging system. To regulate the charging of the battery, the battery charging system usually includes a charging electronics that controls the charging of the battery. The charging process can be regulated according to different charging methods. For example, the charging method may be a constant-current charging method, a pulse charging method or a constant-voltage charging method. In the constant current charging method, the battery is charged with a constant current during the entire charging time. In the pulse charging method, a constant charging current is used according to the principle of pulse width modulation for charging the battery. In the constant voltage charging method, a charging voltage U _{L is} kept constant during the charging time. As charging of the battery progresses, the charge current I _L consumed decreases asymptotically towards zero. As a result, the power consumed by the battery also decreases continuously during the charging process. Also in the constant-current charging method, the pulse charging method or a mixed form of the charging method mentioned above, the power consumed by the battery decreases in the time average.

In return, this means for the energy source connected to the battery charging system, which provides the energy required to charge the battery, that it has to provide, in particular towards the end of the charging process, a power greatly reduced compared to the beginning of the charging process. This can be unfavorable, in particular for the efficiency of the connected energy source. The energy source must either operate away from its optimum operating point, or the charge electronics of the battery charging system must discharge excess power provided by the power source unused. An example of such a poorly controllable energy source are fuel cells, the output voltage is similar to a galvanic cell essentially predetermined by design. A regulation of the output from a fuel cell power is accordingly only with great difficulty by a complicated control of operating temperature, supplied anode gas and supplied cathode gas feasible. The regulation of the output power, however, can lead to a significant reduction in the energy efficiency of the fuel cell. Similar problems can also be found in connection with other energy sources whose output power is not controllable or only with great effort. For example, generators powered by a conventional fuel-powered internal combustion engine must operate the engine at a part load range unfavorable for its energy efficiency to provide the low power desired at the end of the charge phase. An energy-efficient operation of the internal combustion engine near its full-load curve, which approximately indicates the highest efficiency at high and medium engine speeds, is not possible.

The present invention is therefore an object of the invention to provide a battery charging system, which realizes an energy-efficient charging of a battery to be charged even with a no or hardly controllable energy source.

The generic battery charging system according to the invention furthered by the fact that the battery charging system further comprises a residual charge storage, that the charging electronics is adapted to load the residual charge storage with energy from the connectable power source, that the charging electronics is adapted to the connectable battery with energy from the connectable power source teilzuladen, and that the charging electronics is adapted to fully charge the connectable battery with energy from the residual charge storage. In this way, full charging of the battery can be realized without the power source used inefficiently providing low power during charging. Rather, the charging electronics of the battery charging system may keep the power consumed constant throughout the period during which the power source is delivering power. For example, in the case of a constant-voltage charging method, despite decreasing charging currents at the residual charge storage device and the battery to be connected, the total charge current taken from the energy source can be kept substantially constant. As a partial load or partial charging, in particular the charging of the residual charge memory or the charging of the battery, starting from 0% charge capacity to, for example, 30% charge capacity be understood. During the partial charging of the residual charge accumulator, the charging current to be provided by the energy source or the power to be provided by the energy source may be substantially constant.

Advantageous embodiments and further developments are described in connection with the dependent claims.

Usefully, it can be provided that the charging electronics is set up to at least partially charge the residual charge storage with energy from the connectable energy source before the connectable battery is charged. In this way, the empty at the beginning of the charging of the connectable battery remaining storage can be initially charged alone. This limits the maximum charging current to be provided by the energy source or the power to be provided by the energy source at the beginning of the charging process at the beginning of the charging process.

Advantageously, it can be provided that a first switching element for coupling the input terminal to the residual charge memory and a second switching element for coupling the residual charge memory are provided with the output terminal, wherein the first switching element and the second switching element can be controlled by the charging electronics. In this way, the charging electronics can achieve a true decoupling between the energy source, the residual charge storage and the battery to be charged, so that the energy transfer from the energy source to the residual charge storage and / or the battery to be charged can be controlled in an optimal manner.

Furthermore, it can be provided that the input terminal comprises a rectifier. In this way, the use of an AC supplying energy source can be made possible. The rectifier can also protect the battery charging system from reverse polarity at the input terminal. In this context, a switching element for current and / or voltage smoothing can be provided.

It can also be provided that the residual charge storage comprises a capacitor and / or a supercapacitor and / or an accumulator. Capacitor, supercapacitor and / or accumulator are each suitable storage systems, with the help of which electrical energy can be cached within the battery charging system almost lossless. The use of a plurality of identical or different memories for temporary storage of electrical energy within the battery charging system may be provided. There may be provided a selection device by which the storage capacity of the residual charge memory can be adapted to the storage capacity of the battery to be charged. For example, parts of the residual charge memory can be manually switched on and / or switched off.

The generic method is further developed according to the invention that the charging electronics loads a residual charge of the battery charging system with energy from the power source that the charging electronics teillädt the battery with energy from the power source, and that the charging electronics fully charged the battery with energy from the residual charge storage. In this way, the advantages and particularities of the battery charging system according to the invention are also implemented in the context of a method.

Usefully, it may be provided that the charging electronics at least partially cool the residual charge storage with energy from the energy source before the battery is charged.

Advantageously, it can be provided that the charging electronics for coupling or separation of input terminal and residual charge memory drives a first switching element and further controls for coupling or separation of residual charge storage and output terminal, a second switching element.

The invention will now be described by way of example with reference to the accompanying drawings with reference to a preferred embodiment.

Show it:

1 a schematic representation of a battery charging system; and

2 a flow chart of a battery charging process.

In the following drawings, like reference characters designate like or similar parts.

1 shows a schematic representation of a battery charging system. This in 1 illustrated battery charging system 10 includes an output port 12 and an input terminal 16 , In 1 shown in addition to the actual battery charging system 10 in the strictest sense, a battery to be charged 14 connected to the output terminal 12 connected, and an energy source 18 connected to the input port 16 connected. In a broader sense, the battery charging system could 10 always the source of energy 18 be added. The between the output terminal 12 and the battery to be charged 14 illustrated connection symbolizes one or more electrical lines through which the electrical energy from the battery charging system 10 to the battery to be charged 14 is transmitted. In the same way, the illustrated connection symbolizes between the energy source 18 and the input terminal 16 one or more electrical connections between the power source 18 and the battery charging system 10 over which the electrical energy, in particular for charging the battery 14 is used, first to the battery charging system 10 is transmitted. The input connection 16 can be a rectifier 28 comprising, in particular, the battery charging system 10 before a faulty connection of the power source 18 protects. Furthermore, the rectifier 28 the connection of an AC supplying energy source 18 to the battery charging system 10 allow. Next to the rectifier 28 can the input terminal 16 Also include in a manner not shown switching elements that allow a power and / or voltage smoothing.

The battery charging system 10 further includes a charging electronics 20 and a residual load memory 22 , The charging electronics 20 for example, from the at the input port 16 connected power source to be supplied with operating current. The charging electronics 20 can via a control line 36 a first switching element 24 and / or a second switching element 26 to control, ie in particular open and / or close. In this way, as needed, a connection or a separation between the input terminal 16 , the output terminal 12 and the residual store 22 through the charging electronics 20 getting produced. Thus, that of the energy source 18 to charge the battery 14 Provided electric power between the residual charge storage 22 and the battery 14 distributed by the battery charging system 10 the source of energy 18 removed power during charging of the battery 14 keep as constant as possible. Furthermore, a decoupling between the energy source 18 and the battery 14 be realized when the first switching element 24 opened and the second switching element 26 closed is. The first switching element 24 and / or the second switching element 26 can be carried out in a manner known to those skilled in the art for different power ranges with respect to the charging current and the charging voltage.

The charging electronics 20 can at the beginning of charging the battery 14 the first switching element 24 close while the second switching element 26 is open. In this way, initially only the residual charge memory 22 through the energy source 18 loaded. At the same time this limits the maximum charging current that the energy source 18 must provide at the beginning of the charging process and would be significantly larger if at the beginning of the charging process at the same time the remaining memory 22 and the battery 14 getting charged. When the residual store 22 at least partially loaded, the control electronics 20 the second switching element 26 Close, so that from this point on the battery 14 through the energy source 18 is loaded. By closing the second switching element 26 stays by the energy source 18 charging current to be provided approximately constant, although the further charging of the residual charge memory 22 required charging current slowly drops after the part load.

Although the battery 14 at least partially loaded, the control electronics 20 the first switching element 24 open, leaving the energy source 18 no further power to charge the battery 14 is removed. The operation of the charging electronics 20 required electrical energy, for example, the residual charge storage 22 be removed. In this way, the energy source 18 while providing electrical power to charge the battery 14 to operate at its optimum operating point or at least near its optimum operating point. While the battery 14 from the residual store 22 is fully charged, the energy source 18 do not provide performance and can be disabled, for example.

The charging electronics 20 can internally have an electronic circuit that allows her own operating power either directly from the connected power source 18 or via the residual store 22 to acquire.

When the energy source 18 no additional electrical power to charge the battery 14 provides more, since the first switching element 24 in its opened state, the battery becomes 14 exclusively with the help of the residual charge memory 22 loaded. The in the residual store 22 For this purpose, already stored electrical energy can be easily by appropriate previous calculation / dimensioning of the residual charge memory 22 and the charging phases are determined so that the connected battery 14 is fully charged when the residual charge memory 22 is almost discharged. The at the end of charging the battery 14 occurring very low charging currents are not relevant in terms of efficiency in this way. The residual store 22 can have one or more capacitors 30 same or different capacity and / or one or more supercapacitors 32 same or different capacity and / or one or more accumulators 34 same or different capacity. It can be provided parts of the residual charge memory 22 to disable / enable to adjust the capacity of the remaining load memory 22 to realize.

In an in 1 not shown embodiment, the order of the partial charge of residual charge storage and battery can be reversed. For this purpose, a third switching element may be provided, which is the input terminal 16 bypassing the residual store 22 with the output connector 12 can couple. The third switching element can by the charging electronics 20 be controllable.

That in connection with 1 described battery charging system is to perform in connection with 2 described method suitable.

2 shows a flowchart of a battery charging process. This in 2 illustrated method 100 can in step 110 Start by connecting the battery and the power source. If the power source is considered part of the battery charging system, only the battery needs to be connected. Then, according to step 120 the remaining charge storage and / or the battery is charged from the power source. For example, during the first charging phase, only the residual charge storage can be charged by the energy source. During the second charging phase, for example, only the battery can be charged by the power source. The first charging phase may end, for example, when the residual charge storage is at least partially charged. The second charging phase may begin, for example, when the residual charge storage is at least partially charged and may end when the battery is at least partially charged. The third charging phase may be characterized in that both the battery and the remaining charge storage are simultaneously charged by the power source. The fourth charging phase can be characterized in that the energy source provides no further electrical power for charging the residual charge storage and the battery, and that the battery is fully charged or fully charged by the remaining charge storage. Depending on the state of charge of the battery and / or the residual charge storage at the beginning of a specific charging cycle, individual charging phases can be shortened or extended or even completely eliminated. It is also possible that the first charging phase and the second charging phase are reversed. The full charge of the battery from the residual charge storage according to the fourth charging phase corresponds to the in 2 illustrated method 100 step 130 ,

The features of the invention disclosed in the foregoing description, in the drawings and in the claims may be essential to the realization of the invention both individually and in any combination.

LIST OF REFERENCE NUMBERS

10

Battery charging system

12

output port

14

battery

16

input port

18

energy

20

charging electronics

22

Residual load memory

24

first switching element

26

second switching element

28

rectifier

30

capacitor

32

supercapacitor

34

accumulator

36

control line

100

method

110

Connect battery and power source

120

Load residual storage and / or battery from energy source

130

Charge battery from remaining charge storage

Claims (8)

Battery charging system ( 10 ) with an output terminal ( 12 ) to the one battery to be charged ( 14 ) and an input terminal ( 16 ) to the one energy source ( 18 ), wherein the battery charging system ( 10 ) a charging electronics ( 20 ) for controlling a charging process, characterized in that - the battery charging system ( 10 ) further a residual charge memory ( 22 ), that the charging electronics ( 20 ) is set up to store the residual store ( 22 ) with energy from the connectable energy source ( 18 ), - that the charging electronics ( 20 ) is set up to connect the connectable battery ( 14 ) with energy from the connectable energy source ( 18 ), and - that the charging electronics ( 20 ) is set up to connect the connectable battery ( 14 ) with energy from the residual store ( 22 ). Battery charging system ( 10 ) according to claim 1, characterized in that the charging electronics ( 20 ) is set up to store the residual store ( 22 ) with energy from the connectable energy source ( 18 ) at least partially before the connectable battery ( 14 ) is loaded. Battery charging system ( 10 ) according to claim 1 or 2, characterized in that a first switching element ( 24 ) for coupling the input terminal ( 16 ) with the residual store ( 22 ) and a second switching element ( 26 ) for coupling the residual charge memory ( 22 ) with the output terminal ( 12 ) are provided, wherein the first switching element ( 24 ) and the second switching element ( 26 ) from the charging electronics ( 20 ) are controllable. Battery charging system ( 10 ) according to one of the preceding claims, characterized in that the input terminal ( 16 ) a rectifier ( 28 ). Battery charging system ( 10 ) according to one of the preceding claims, characterized in that the residual store ( 22 ) a capacitor ( 30 ) and / or a supercapacitor ( 32 ) and / or an accumulator ( 34 ). Procedure ( 100 ) for charging one at an output terminal ( 12 ) of a battery charging system ( 10 ) connectable battery ( 14 ), to an input terminal ( 16 ) of the battery charging system ( 10 ) an energy source ( 18 ) and to the output port ( 12 ) the battery ( 14 ), characterized in that - the charging electronics ( 20 ) a residual store ( 22 ) of the battery charging system ( 10 ) with energy from the energy source ( 18 ), - that the charging electronics ( 20 ) the battery ( 14 ) with energy from the energy source ( 18 ), and - that the charging electronics ( 20 ) the battery ( 14 ) with energy from the residual store ( 22 ) fully loaded. Procedure ( 100 ) according to claim 6, characterized in that the charging electronics ( 20 ) the residual store ( 22 ) with energy from the energy source ( 18 ) at least partially before the battery ( 14 ) is loaded. Procedure ( 100 ) according to claim 6 or 7, characterized in that the charging electronics ( 20 ) for coupling or disconnecting input terminal ( 16 ) and residual store ( 22 ) a first switching element ( 24 ) and continues to couple or separate residual storage ( 22 ) and output terminal ( 12 ) a second switching element ( 26 ).

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