DE102014222610A1 - Power supply device with a non-rechargeable galvanic cell and a rechargeable galvanic cell - Google Patents

Abstract

Disclosed is an arrangement with a non-rechargeable galvanic cell (1), a rechargeable galvanic cell (2) and a control unit (3). The non-rechargeable galvanic cell generates a first voltage (V1) and is electrically connected to the load (4) for feeding a first current (I1) into the load. The rechargeable galvanic cell generates a second voltage (U2) and is electrically connected via the control unit to the load and the non-rechargeable galvanic cell for feeding a second current (I2`) into the load. The control unit is designed to receive at least one control signal (S1) and to adjust the strength of the second current based on the at least one control signal such that the first current is limited by the second current (I2 ') and does not exceed a predetermined threshold value. The at least one control signal represents at least one of the quantities first voltage, second voltage and first current.

Description

The invention relates to a power supply device with a non-rechargeable galvanic cell and a rechargeable galvanic cell. Such a device can be used in particular for supplying a remote control unit, for example for a vehicle, with energy.

In many areas, such as in the automotive sector, remote controls are used today to control a wide variety of applications. For example, in vehicles remote controls can be used to lock and unlock the doors, to open and close covers of vehicle openings such as trunk lids or windows, or to activate or deactivate alarm systems. Furthermore, remote controls in the automotive sector are often used as identification units, which check the access authorization to the vehicle.

The remote controls have various necessary components for their function, which must be supplied with energy. That's why remote controls have an internal power supply. Such internal power supplies often include a non-rechargeable galvanic cell and a rechargeable galvanic cell. The electrochemical reaction of the non-rechargeable galvanic cell is irreversible, so that once consumed, it can not be reused. Such a non-rechargeable galvanic cell is also referred to as a primary cell. By contrast, the electrochemical reaction of the rechargeable galvanic cell is reversible so that it can be recharged. Such rechargeable galvanic cells are also referred to as secondary cells. An interconnection of several similar galvanic cells is commonly referred to as a battery. For batteries with rechargeable galvanic cells is often the term "accumulator" use.

There are remote control units with a primary cell and a secondary cell are known in which the required energy is always provided either from either the primary cell or from the secondary cell. Whether the energy is supplied by the primary cell or the secondary cell depends on the respective state of charge. If the primary cell is completely discharged, it must be replaced. If the secondary cell is discharged, it must be recharged.

The charging of the secondary cell can be done, for example, contact or contactless (eg, inductive) by means of a suitable charger. However, remote control systems are also known in which the secondary cell is recharged by the primary cell also located in the remote control. Such a remote control device is for example from the DE 10 2009 033 309 A1 known.

The primary cell and the secondary cell usually have different nominal voltages in such charging circuits. If the rated voltage of the secondary cell is above the nominal voltage of the primary cell, an up-converter is required to charge the secondary cell from the primary cell. However, this causes losses, which reduces the efficiency of the charging circuit.

However, charging circuits are also known in which the primary cell and the secondary cell have rated voltages which do not differ significantly from one another. For example, the actual voltage across the primary cell may only be about 0.2 V above the actual voltage of the secondary cell. In such cases, the secondary cell can be connected directly to the primary cell for charging. However, this initially breaks the voltage of the primary cell accordingly. Such a charging circuit is often referred to as an unregulated charging circuit. In unregulated charging circuits, however, too high charging currents can occur, for example in the case of unfavorable internal resistance of the secondary cell, which can cause permanent damage to the primary or secondary cell. In addition, unregulated charging circuits are usually less energy efficient.

Object of the present invention is to provide an arrangement with a primary cell and a secondary cell available, which causes no damage to the cells and is as efficient as possible.

This object is solved by the independent patent claims. Embodiments and developments of the invention are the subject of dependent claims.

An arrangement according to the invention comprises at least one non-rechargeable galvanic cell, at least one rechargeable galvanic cell and a control unit. The non-rechargeable galvanic cell generates a first voltage and is electrically connected to a load for supplying a first current to the load. The rechargeable galvanic cell generates a second voltage and is electrically connected through the control unit to the load and the non-rechargeable galvanic cell for supplying a second current to the load cell Consumer. The control unit is designed to receive at least one control signal and, based on the at least one control signal, to set the strength of the second current such that the first current is limited by the second current and does not exceed a predetermined threshold value. The at least one control signal represents at least one of the first voltage, the second voltage and the first current.

The consumer is thus always supplied with electrical energy both from the non-rechargeable galvanic cell and from the rechargeable galvanic cell. A maximum amount of energy is provided by the non-rechargeable galvanic cell. As a result, only a minimum amount of current is drawn from the rechargeable galvanic cell, so that only a small amount of current has to be recharged into the rechargeable galvanic cell. As a result, the losses of the arrangement when charging the rechargeable galvanic cell from the non-rechargeable galvanic cell are low. Another advantage of the power supply device according to the invention is that it can be easily prevented that the second current flows while the non-rechargeable galvanic cell is removed from the device, for example, to replace it. The rechargeable galvanic cell can thus be protected against damage.

The control unit can be found not only in the removal of power from the non-rechargeable galvanic cell use, but also to control the current when charging the rechargeable galvanic cell.

The control unit may for example comprise an amplifier unit which has a first input terminal, a second input terminal and an output terminal, wherein the inputs of the amplifier unit are adapted to receive control signals. One of the two control signals at the inputs of the amplifier unit can represent the first voltage. One of the two control signals at the inputs of the amplifier unit may also represent the first current. This makes it easy to implement an amperage control depending on these quantities. When taking the current from the galvanic cells, peculiarities of the non-rechargeable galvanic cell can be taken into account, since with the regulation according to the invention a dependency of the maximum first current on the temperature and the voltage of the non-rechargeable galvanic cell can be represented.

If the first voltage is less than or equal to the second voltage, the control unit may comprise a controllable resistor whose resistance changes as a function of the control signal.

On the other hand, if the first voltage is less than the second voltage, the control unit may comprise a buck converter. If the first voltage is greater than the second voltage, the control unit may include a boost converter.

A device described above may be used together with a consumer in a remote control device.

The invention will be explained in more detail with reference to the embodiments illustrated in the figures of the drawings, wherein like elements are provided with the same reference numerals. It shows:

1 a block diagram of an arrangement with a primary cell and a secondary cell; and

2 in a block diagram another arrangement with a primary cell and a secondary cell.

In 1 is a block diagram of a power supply device with a primary cell 1 and a secondary cell 2 shown. The primary cell 1 is between a reference potential GND and a terminal of a consumer 4 whose other terminal is connected to the reference potential GND connected, and provides an electrical voltage U1 available. The electrochemical reaction of the primary cell 1 is irreversible so it can not be recharged once discharged.

A secondary cell 2 is between the reference potential GND and the one terminal of the consumer 4 (Circuit node between primary cell 1 and consumers 4 ) and provides an electrical voltage U1 available. The electrochemical reaction of the secondary cell 2 runs reversibly, so that the secondary cell 2 recharge.

Between the secondary cell 2 and the common circuit node of the primary cell 1 and the consumer 4 is a control unit 3 connected, which may also be connected to the reference potential GND. In the control unit 3 a current flows I2 and from the control unit 3 a current I2 'flows to the primary cell 1 and the parallel consumer 4 , The control unit 3 receives a control signal S1 and is adapted to the Amperage I2 'in response to the control signal S1 set. The control unit 3 then provides electrical energy with a set current I2 'available. By the consumer 4 thus flows a current with a current I3, the current I3 depends on the current I1 and the set current I2 '. Ideally, currents I2 and I2 'have the same magnitude. The current I2 'limits the current I1, so that it does not exceed a certain threshold.

The consumer 4 is thus through the primary cell 1 and the secondary cell 2 energized. This is where the consumer sits 4 provided electrical energy always from a (maximum) share of one through the primary cell 1 provided electrical energy and a (residual) share of a through the secondary cell 2 provided electrical energy. From the secondary cell 2 In most cases, only a small amount of electricity is always withdrawn. The secondary cell 2 As a result, it does not discharge as quickly as it does with the sole supply of the consumer 4 through the secondary cell 2 the case would be. The secondary cell 2 must therefore at the in 1 shown arrangement are charged less frequently, or it must be recharged only a small amount of power.

However, it is also possible, the current I2 through the control unit 3 to zero (current I2 'is zero). In this case, the consumer becomes 4 alone through the primary cell 1 supplied with electrical energy. In this way, the secondary cell 2 protected and their life extended. The control signal S1 can, for example, from the voltage U1 of the primary cell 1 and / or the voltage U2 of the secondary cell 2 depend.

The control unit 3 For example, it may include an adjustable resistor when the voltage of the secondary cell 2 only slightly larger than the voltage of the primary cell 1 (eg approx. 0.2 V). The adjustable resistor can be changed accordingly to set the current I2. The adjustable resistor is between the primary cell 1 and the secondary cell 2 switched, wherein the current I2 is equal to the current I2 '.

Is the voltage of the secondary cell 2 significantly above the voltage of the primary cell 1 can the control unit 3 For example, include a buck converter. By contrast, lies the voltage of the secondary cell 2 under the voltage of the primary cell 1 , can the control unit 3 comprise a boost converter.

The current intensity I2 can be adjusted, for example, as a function of the current intensity I1. The current I1 changes (apart from load fluctuations of the consumer), for example, as a function of the (actual) voltage of the primary cell 1 and the voltage of the primary cell 1 changes, for example, depending on the temperature or depending on the state of charge of the primary cell 1 ,

2 shows in a block diagram another example of a power supply device with a primary cell 1 and a secondary cell 2 , The primary cell 1 is connected via a resistor R1 to the reference potential GND. A voltage divider having a series connection of a second resistor R2 and a third resistor R3 is connected between the terminal for the reference potential GND and a common circuit node of the control unit 3 and the primary cell 1 connected.

An operational amplifier 5 is connected to a first input terminal E1 having a common circuit node of the primary cell 1 and the first resistor R1. With its second input terminal E2 is the operational amplifier 5 is connected to a common circuit node of the second resistor R2 and the third resistor R3. At an output terminal A1, the operational amplifier provides 5 the control signal for the transistor T available.

The operational amplifier 5 compares a voltage present at its first input terminal E1 (control signal S2) with a voltage applied to its second input terminal E2 (control signal S3). The difference between the two voltages is amplified and output at the output terminal A1 as a control signal. Includes the control unit 3 an adjustable resistor, its resistance is changed depending on the amplified voltage difference. The control unit 3 For example, it may comprise a transistor T controlled in response to the amplified voltage difference. In this way, the current strength of the current I2 ', which is substantially equal to the current strength of the current I2 changes. The voltage applied to the input terminal E1 is the voltage across the resistor R1 and thus proportional to the current through the resistor R1. The current through the resistor R1 is substantially equal to the current I1. The voltage applied to the input terminal E2 is proportional (according to the division ratio of the voltage divider) of the voltage across the load 4 and thus equal to the voltage U1 plus the voltage across the resistor R2, ie substantially the voltage U1, since this is substantially greater than the voltage across the resistor R2. Thus, in the present example, the voltage U1 and the current 1 the primary cell 1 used to control the current I2 '.

A device described above can be used together with a consumer, for example in a particular portable remote control device can be used. In this case, the consumer may in particular be a transmitting device for transmitting a radio signal or a transmitting / receiving device for transmitting and receiving a radio signal.

Furthermore, there can be provided a remote control apparatus for a vehicle which comprises, on the one hand, a remote control apparatus mentioned above, and a vehicle side receiver for receiving the radio signal transmitted from the (portable) remote control apparatus, further comprising an on-vehicle functional means for performing a vehicle function in response to the reception of the vehicle Radio signal is provided.

LIST OF REFERENCE NUMBERS

1

non-rechargeable galvanic cell

2

rechargeable galvanic cell

3

control unit

4

consumer

5

amplifier unit

T

transistor

E1

first input connection

E2

second input connection

A1

output port

S1

control signal

S2

control signal

S3

control signal

R1

first resistance

R2

second resistance

R3

third resistance

U1

first tension

U2

second tension

I1

first stream

I2

second stream

I2 '

 set second current

I3

third stream

GND

 reference potential

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009033309 A1 [0005]

Claims (9)

Power supply device for a consumer ( 4 ), which is a non-rechargeable galvanic cell ( 1 ), a rechargeable galvanic cell ( 2 ) and a control unit ( 3 ), wherein the non-rechargeable galvanic cell ( 1 ) generates a first voltage (U1) and with a consumer ( 4 ) is electrically connected to the feeding of a first current (I1) into the consumer ( 4 ); the rechargeable galvanic cell ( 2 ) generates a second voltage (U2) and via the control unit ( 3 ) with the consumer ( 4 ) and the non-rechargeable galvanic cell ( 1 ) is electrically connected to the supply of a second current (I2 ') in the consumer ( 4 ); the control unit ( 3 ) is adapted to receive at least one control signal (S1, S2, S3) and based on the at least one control signal (S1, S2, S3) to adjust the strength of the second current (I2 ') such that the first current (I1) the second current (I2 ') is limited and does not exceed a predetermined threshold value, and the at least one control signal (S1, S2, S3) represents at least one of the quantities first voltage (U1), second voltage (U2) and first current (I1) , Device according to claim 1, wherein the control unit ( 3 ) an amplifier unit ( 5 ) having a first input terminal (E1), a second input terminal (E2) and an output terminal (A1) and the inputs (E1, E2) of the amplifier unit ( 5 ) are designed to receive control signals (S2, S3). Device according to claim 2, wherein one of the two control signals (S2) at the inputs (E1, E2) of the amplifier unit ( 5 ) represents the first voltage (U1). Device according to claim 2 or 3, wherein one of the two control signals (S3) at the inputs (E1, E2) of the amplifier unit ( 5 ) represents the first stream (I1). Device according to one of claims 1 to 4, wherein the first voltage (U1) is less than or equal to the second voltage (U2) and the control unit ( 3 ) comprises a variable resistor. Device according to one of claims 1 to 4, wherein the first voltage (U1) is smaller than the second voltage (U2) and the control unit ( 3 ) comprises a down converter. Device according to one of claims 1 to 4, wherein the first voltage (U1) is greater than the second voltage (U2) and the control unit ( 3 ) comprises an up-converter.  Remote control device, in particular for a vehicle, comprising the following features: - a consumer; and - A power supply device according to one of the preceding claims 1 to 7.  Apparatus according to claim 8, wherein the consumer comprises a transmitter.

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