EP1911138A1

EP1911138A1 - Apparatus and method for charging a first battery from a second battery

Info

Publication number: EP1911138A1
Application number: EP06762944A
Authority: EP
Inventors: Herbert Schein; Bernd Behnle; Eduard Pytlik; Dejan Ilic
Original assignee: VARTA Microbattery GmbH
Current assignee: VARTA Microbattery GmbH
Priority date: 2005-08-05
Filing date: 2006-08-02
Publication date: 2008-04-16
Also published as: US8120309B2; WO2007017164A1; JP2009504124A; US20090315508A1; CN101238627A

Abstract

A charging device (11) for charging a first battery (3) in the form of a rechargeable battery button cell from a second battery (2) has a housing (12) having a battery receptacle (13). The first battery (3) to be charged and the second charging battery (3) are inserted into the charging device (11) together with a component having a charging circuit (4). Batteries (3) for hearing devices, for example, which, as rechargeable batteries, only allow for operation which is too short can thus be recharged in transit. The charging batteries (2) may have a standard design which is available universally.

Description

description

Apparatus and method for charging a first battery from a second battery

Field of application and state of the art

The invention relates to a charger or a device for charging at least one first battery from at least one or at least one second battery and a method for this purpose.

For charging such a first battery, which can also be regarded as an accumulator, there are generally different chargers. Typical chargers are supplied with mains voltage, whereby their use is localized or at least tied to an insert together with sockets or fixed supply devices. Furthermore, there are chargers that charge batteries with electricity from solar cells. These are also portable. Of course, they need light to function. Furthermore, they are relatively unwieldy because of the required size of the solar cells.

Problems with the charging of the aforementioned rechargeable batteries or accumulators occur especially when using devices that have short durations with rechargeable batteries, which may be about the order of a day, partly about it, but under certain circumstances also significantly less a day depending on, for example, the age of the battery or environmental conditions. Here a user is reliant on always carrying a supply of charged batteries, which means some inconvenience. The batteries must also be in a transport packaging, and above all a distinction must be made between charged and already discharged batteries. This can lead to confusion, which is disturbing in many cases. Typical such devices are hearing aids. At present, they are usually operated with primary batteries, so-called button cells. This results in terms of the order of a few days to even weeks. If instead of rechargeable secondary batteries or rechargeable batteries are used instead of only once usable button cells, for example of the type nickel / metal hydride, then the above maturities result. Thus, replacement or replacement of the battery may also be necessary during the day away from home, with the problems of having to carry multiple charged batteries or replacement batteries of sufficient capacity. If the runtime is more than one day, then the problem of change may occur the next day, so again in the middle of the day. For this reason, for example, the above-mentioned nickel / metal hydride type secondary batteries have not yet become established for hearing aids.

Task and solution

The invention has for its object to provide an aforementioned charger and a charging method with which problems of the prior art can be avoided and is particularly portable and handy for comfortable use.

This object is achieved by a charger with the features of claim 1 and a method having the features of claim 16. Advantageous and preferred embodiments of the invention are the subject of further claims and will be explained in more detail below. tert. The wording of the claims is made explicit reference to the content of the description.

According to the invention, it is provided that both the first battery to be charged and the second charging battery are arranged or accommodated in the charger. So they can not fall out. In this case, the capacity of the first battery to be charged is substantially lower than that of the at least one or more second charging batteries. While the first battery to be charged is a secondary battery, that is, an accumulator, a rechargeable battery may be both. On the one hand, it is possible that the charging battery is also an accumulator or a secondary battery. Because of their considerably larger capacity, it must be charged only at long intervals, so that it can be expected that for the time required from time to time charging the rechargeable battery, an aforementioned power supply or a socket are available. Alternatively, a normal primary battery can be used as a charging battery, for example in a handy and widely available form of the type Mignon or Baby or LR03 or LR6. Since there are both primary batteries and accumulators in this format, it can also be left to a user to equip the charger according to his needs.

In one embodiment of the invention it can be provided that the first battery is to be arranged in a different receptacle of the charger than the charging battery. Thus, confusion can be avoided. Furthermore, it is possible to provide different receptacles for first batteries to be charged and / or for different charging batteries on the charger. Thus, a single type of charger can be used uni versilily, in particular, various currently available charging batteries can be used. This is especially for the aforementioned use on the move or while traveling of great advantage.

In another embodiment of the invention, it is possible that both the battery to be charged and one or more charging batteries are arranged in the same receptacle or in a battery compartment of the charger. This makes the charger easier to design. Furthermore, insertion of both the first battery and the at least one charging battery can be easily performed in the same manner.

Thus, the charger can be transported well and is manageable, it may be elongated according to a conventional battery shape. Thus, a plurality of batteries, in particular a plurality of charging batteries, can be arranged one behind the other in the charger. This is known, for example, from so-called flashlights.

For controlling the charging process, in particular for adaptation of charging voltage and / or charging current, a so-called charging circuit may be provided. This can in particular be designed so that always takes place with different numbers of charging batteries and thus different levels of available voltage always a good charge of the first battery to be charged. For voltage conversion, either the voltage of the charging batteries can be reduced to adapt to the voltage required for the battery to be charged. In a further embodiment of the charger, it is possible that with the provision of only one charging battery, for example, with a Hochsetz- actuator voltage conversion can take place in order to achieve the necessary for charging the first battery voltage.

Furthermore, it is possible that the charging circuit makes a limitation of the charging current. In addition, it can still be provided that can be changed between different charging modes. For example, a very fast charging with a high charging current can take place. This is particularly advantageous if the battery to be charged is needed again as quickly as possible. However, if no fast charging is required, a considerably gentler charging with usual or optimum charging current can take place, which can then be considerably lower.

The charging circuit may terminate the charging process under certain circumstances automatically. For this purpose, either the achievement of a voltage at the battery to be charged can be monitored. Alternatively, it can be detected via the charging current, whether the battery to be charged has reached a defined state of charge. Furthermore, the charging circuit may have a charging electronics, are realized by the various aforementioned functions. Another such function may be a timer function, in particular for terminating the charging process after a certain time.

On the one hand, it is possible that the charging circuit is integrated in the charger and not directly accessible, except possibly by an on / off switch. Alternatively, the charging circuit may be contained in a separate component. This can then be used for example in a battery holder or a battery compartment between the first battery to be charged and the charging batteries. It is thus possible, for example, to adapt to different batteries to be charged in a single housing for a charger by replacing the component with the charging circuit.

In order to increase the ease of use of the charger, a switch for disconnecting the battery to be charged from a rechargeable battery may be provided. A break contact of the switch should be as close as possible to one of the batteries. Is he as close as possible to one Pol, in particular the positive pole, one of the charging batteries provided so they can be separated directly and it can flow no discharge current, so that their capacity is conserved as possible. The same can be provided for the first battery to be charged so that it is not discharged again after charging as far as possible.

Furthermore, it may be provided for a charging circuit that it terminates the charging process after completion. For the prolonged whereabouts of the first battery in the charger while at the same time avoiding discharging or maintaining the full state of charge, a charge-sustaining mode can be provided. In this mode, the charging circuit monitors the state of the battery being charged. As soon as it has discharged to a certain extent, it will be recharged automatically. This ensures that in the charger always as a kind of stock a fully charged first battery is present and can be removed for use.

Advantageously, an optical display can be provided to increase the ease of use, which represents an operating state of the charger or a state of charge or a capacity indicator of the charging batteries. Good visible light indicators are considered here advantageous, especially power-saving LED. A connection of the light indicator to one of the batteries is as direct as possible, whereby this connection can be separated by an aforementioned switching device to obtain the state of charge of the batteries.

These and other features are apparent from the claims and from the description and the drawings, the individual features each alone or more in the form of sub-combinations in an embodiment of the invention and in other fields be realized and advantageous and for can represent protectable versions for which claims protection here becomes. The subdivision of the application into individual sections and subheadings does not restrict the general validity of the statements made thereunder.

Brief description of the drawings

Embodiments of the invention are shown schematically in the drawings and will be explained in more detail below. The drawings show:

1 is a sectional view of an inventive charger with exploded view of the items,

2 to 4 different interconnections of the charger of FIG. 1st

Detailed description of the embodiments

In Fig. 1, a charger 11 is shown in section. It has in a housing 12, the interior of which forms a battery compartment or a receptacle 13, two charging batteries 2. These are advantageously primary batteries, for example alkali / manganese LR03, LR6. These are common, user-replaceable batteries. They are arranged one behind the other in the charger 11.

Furthermore, there is in the receptacle 13 directly thereafter or about a charging circuit 4 with charging electronics. This determines the progress of the charging process. A battery 3 to be charged has the shape of a button cell and is for example of the type nickel / metal hydride, as they are advantageously used for hearing aids. It is still arranged on the charging circuit 4 in the receptacle 13. Be closed can the housing 12 with the front cover 14, the plugged o- can be screwed. In the lid 14, an LED 6 is provided as a light indicator that can inform about various operating conditions.

At the other end, the charger 11 has a switch 5. This can, as will be shown and described below, to interrupt contacts, as well as information about a charging or operating state.

The housing 12 here has a small form, preferably a slender cylindrical pin shape, so that it can be conveniently carried on the body and is readily available. For this purpose, the clip can be provided. The batteries 2 and 3 are arranged in the single receptacle 13, as is the charging circuit 4. Alternatively, receptacles for batteries of different sizes may be provided.

In Fig. 2 is a schematic representation of the electrical interconnection is shown. The charging circuit 4, possibly with a charging electronics, is arranged between the battery 3 to be charged and the charging batteries 2. So she can control the charging process.

In the extension of FIG. 3, a switch 5 between charging circuit 4 and charging batteries 2 is still provided. Alternatively or additionally, it can be provided between the charging circuit 4 and the battery 3 to be charged, under certain circumstances as a switch with two contacts. It separates the charging battery 2 from the charging circuit 4. Thus, it can be reliably prevented that residual currents flow when not charging and thus energy is wasted.

In a similar extension according to FIG. 4, the LED 6 is arranged between charging circuit 4 and charging batteries 2. Also another LED may alternatively or additionally be provided between charging circuit 4 and battery 3 to be charged. It can display the three operating states "charge", "charge completed" and "charge battery empty." Combinations with switches 5 and 6 can also be provided.

The capacity of the battery 3 to be charged is substantially lower than that of the charging batteries 2. Thus, a large number of charges can be carried out from the charging batteries 2, typically 10 to 100 charges are possible. The battery 3 to be charged is a small battery, typically in the form of a coin cell. All available electrochemical systems can be used (eg nickel / metal hydride and various lithium systems). Parallel and series circuits of batteries 3 can also be charged.

The intermediate charging circuit 4 or charging electronics can perform various functions. When the voltage of the charging battery 2 is higher than that of the battery 3 to be charged, the charging circuit 4 can limit the charging current. It can end the charge on reaching a final voltage or after a defined time. If the voltage of the charging battery 2 is lower than that of the battery 3 to be charged, a charging circuit 4 with a voltage converter function can be used.

The advantages of this charger are: - Comfort: The charger is small, light and pleasant to use

- Mobility: The charger can be worn like a pen and is ready at any time.

- Safety: A hearing aid user always has a charged battery or button cell 3 ready. Thus, listening is possible without interruption. - Availability: Replacement rechargeable batteries are standard and therefore available worldwide and cheaply. The battery 3 is also standardized and can be used for various devices.

Examples include with

Example 1 :

Two charging batteries 2 of the type alkali / manganese LR03 with a capacity of 1000 mAh are connected in series. The battery 3 to be charged is of the type NiMH size PR48 with a capacity of 30 mAh. The interposed charging circuit 4 limits the current to 6 mA (corresponding to 0.2 CA). In this circuit, the battery 3 to be charged is charged in 6 hours, so it can be carried out 28 charging processes with a set of charging batteries 2.

Example 2:

Three charging batteries 2 of the type alkali / manganese LR03 with a capacity of 1000 mAh are connected in series. To be loaded is a series connection of two button cells 3 of the type NiMH size PR48 with a capacity of 30 mAh. The charging circuit 4 connected in between limits the current to 6 mA (corresponding to 0.2 CA). In this circuit, the battery to be charged 3 is charged in 6 hours, 28 charging operations can be performed with a set of charging batteries 2. Example 3:

Two charging batteries 2 of type alkali / manganese LR6 with a capacity of 2400 mAh are connected in series. The battery 3 to be charged is of the type NiMH size PR48 with a capacity of 30 mAh. The interposed charging circuit 4 limits the current to 6 mA (corresponding to 0.2 CA). In this circuit, the battery 3 to be charged is charged in 6 hours, 66 charges can be performed with such a set of charging batteries 2.

Example 4:

Two recharge batteries 2 of type nickel / metal hydride HR03 with a capacity of 700 mAh are connected in series. The battery 3 to be charged is of the type NiMH size PR48 with a capacity of 30 mAh. The interposed charging circuit 4 limits the current to 6 mA (corresponding to 0.2 CA). In this circuit, the battery to be charged 3 is charged in 6 hours, 19 charging operations can be performed. Then the charging batteries 2 must be recharged.

Example 5:

A charging battery 2 of the type alkali / manganese LR03 with a capacity of 1000 mAh is used. To charge is a series connection of two button cells as batteries 3 of type NiMH size PR48 with a capacity of 30 mAh each. The intermediate charging circuit 4 converts the voltage to a value of 3V and limits the current to 6 mA (corresponding to 0.2 CA). In this circuit will be Charging the batteries 3 to be charged in 6 hours, 13 charging operations can be performed with a charging battery 2.

Claims

claims

A charger for charging at least a first battery (3) from at least a second battery (2), wherein the first battery to be charged and the second charging battery are disposed in the charger (11), and wherein the capacity of the first to be charged battery (3) is substantially lower than that of the second charging battery (2).

2. Battery charger according to claim 1, characterized in that the first battery to be charged (3) can be arranged in a different receptacle of the charger than the charging battery (2).

3. Charger according to claim 1 or 2, characterized in that recordings for different sizes of the first battery to be charged (3) and / or the charging battery (2) are provided.

4. A charger according to claim 1, characterized in that the first to be charged battery (3) in the same receptacle (13) of the charger can be arranged as the charging battery (2), preferably the first battery (3) in the same way and Way in the recording can be used as the charging battery (2).

5. Battery charger according to one of the preceding claims, characterized in that the charger (11) is elongate and a plurality of batteries (2, 3) are arranged one behind the other, preferably a plurality of charging batteries (2) in a row.

6. Charger according to one of the preceding claims, characterized in that the charging battery (2) has elongated cylindrical shape, in particular of the type Mignon or Baby is.

7. Charger according to one of the preceding claims, characterized by a charging circuit (4) which is designed to adapt the charging voltage and / or the charging current.

8. Battery charger according to claim 7, characterized in that the charging circuit (4) is designed to terminate the charging process, preferably after reaching a final voltage of the first battery to be charged (3) or after a defined time.

9. Charger according to claim 7 or claim 8, characterized in that the charging circuit (4) is designed for voltage conversion, preferably with a step-up converter.

10. Battery charger according to one of claims 7 to 9, characterized in that the charging circuit (4) is designed to limit the charging current.

11. Battery charger according to one of claims 7 to 10, characterized in that the charging circuit (4) has a charging electronics, preferably for a timer function.

12. Battery charger according to one of claims 7 to 11, characterized in that the charging circuit (4) is a self-handle component, preferably for insertion into a battery receptacle (13) between the first battery to be charged (3) and the charging Battery (2).

13. Battery charger according to one of the preceding claims, characterized by a switch (5) for disconnecting the first battery to be charged (3) of the charging battery (2), wherein in particular the switch (5) as close as possible a disconnect contact in particular, the switch (5) as close as possible to one of the two batteries (2, 3) has an isolating contact, in particular at the positive pole of the charging battery (2).

14. Charger according to one of the preceding claims, characterized by an optical display for operating states of the charger or a state of charge of the first battery to be charged (3) or the operating state of the charging battery (2), preferably as a light indicator, in particular as an LED (6 ).

15. A charger according to claim 14, characterized in that the optical display (6) either directly to the first battery to be charged (3) or the charging battery (2) is provided or is connected thereto.

16. A method for charging a first battery (3) from a second battery (2) with a charger (11), wherein the charger is designed according to one of the preceding claims.