NL2000276C2 - Battery recharging circuit for portable electronic device, e.g. mobile phone, has output linked to inputs via connections with voltage converters for generating common charge voltage - Google Patents

Abstract

The circuit (P2) has at least two inputs (I1-I3) for connecting a recharger and an output (U1) for connecting to a power supply port for the device, via which the power for recharging the battery is received. Each input makes contact via a connection with a junction point (K) for the output. At least one of these connections includes a voltage converter (S1, S2) which converts a supplied power voltage into a common charge voltage for delivery to the output. An independent claim is also included for a casing for this circuit, which has a round shape, the output connection and connectors being located in a peripheral surface of this casing.

Description

Circuit for charging portable electronics

The present invention relates to a circuit for charging portable electronics. In addition, the invention relates to a charger for portable electronics.

A portable electronic device such as a mobile phone, an electronic diary, a music player or a portable computer is provided with a battery that can provide electrical power to the portable device.

By using the battery, the portable electronic device can be used at any place, independently of a connection to the fixed electricity grid.

When the battery runs out, the battery of the electronic device must be recharged in order to continue using the device. This charging can be carried out by a charger which is coupled to an electrical input of the electronic device and which can store electrical power from the electricity grid in the battery.

The charger is hereby able to convert the alternating voltage of the electricity grid into a suitable supply voltage for the battery.

Such a charger is usually supplied to the user together with the portable electronic device.

Often the electronic device and the associated charger have specific matched connectors in terms of shape and also in terms of position of electrical connection pins within the connector. For example, for mobile telephones, the connection of the charger to the telephone is different for each brand and in some cases also different for specific telephone models within a brand.

The supply voltage of the electronic device is also often specific. The supply voltage value of the charger that is used often varies by brand and sometimes also by model within a brand.

This means that a user can only use the same charger as associated with an electronic device of the same brand and / or model.

30 Many users consider taking the charger uncomfortable and / or restrictive. Lowering the battery of portable electronics often happens at a random moment and at a random place. If the user does not have a charger with him and the battery of the portable electronic device runs out, finding a usable charger can be a problem at that time.

It is an object of the present invention to improve the possibilities for charging a portable electronic device.

This object is solved by a circuit for charging portable electronics according to claim 1.

Advantageously, the circuit according to the present invention ensures that an applied supply voltage is converted into a usable charging voltage for the electronic device.

It appears that despite differences in supply voltage value between electronic portable devices such as mobile phones, the battery used in these devices is very often suitable for charging at a charging voltage other than the supply voltage value used by the manufacturer of the device.

This general charging voltage can be applied to the power supply connection of the electronic device without damaging the internal circuits of the electronic device.

Therefore, the circuit for a charger in use provides the general charging voltage at its output.

Furthermore, the circuit according to the present invention makes it possible to use a different charger than the charger that belongs to the electronic device and that happens to be available to the user. Due to the wide distribution of mobile electronic devices, such a charger is often available in very many places.

In a further embodiment, the circuit is also capable of receiving a separately available battery and connecting it to the output of the circuit to provide the general charging voltage at the output in use.

It is advantageously achieved in this way that in the case that no charger is available, a possibility is nevertheless offered to supply the electronic device with voltage.

Further embodiments of the circuit according to the present invention are described in the subclaims.

3

The invention will be explained in more detail below with reference to a few drawings, in which some exemplary embodiments are shown. The drawings are intended for illustrative purposes only, and are not intended to limit the inventive concept, which is defined by the appended claims.

5 Show:

Figure 1 shows a first embodiment of the circuit for a charger;

Figure 2 a second embodiment;

Figure 3 shows an example of a configuration in which the circuit is included;

Figure 4 shows a second example of a configuration in which the circuit is included;

Figure 5 shows a third embodiment of the circuit for a charger, and

Figure 6 shows in detail an embodiment of a voltage comparator as shown in Figure 5, and

Figure 7 shows a fourth embodiment of the circuit for a charger.

Figure 1 shows schematically a first embodiment of the circuit.

The circuit according to the invention can be used for various types of portable electronic devices with a rechargeable battery, such as mobile telephones, pocket computers and portable computers such as laptops or notebooks, music players (for example mp3 players), and electronic diaries. The circuit for use with mobile telephones will be explained below as an example.

The circuit P comprises a number of inputs II, 12, 13, and an output U1. The first, second and third input II, 12, 13 are connected to output U1 via a node or connection point K.

In the connection between first input II and node K, a first voltage regulator S1 is included.

A second voltage regulator S2 is included in the connection between second input 12 and node K.

The third input 13 is directly connected to node K.

In order to prevent mutual influence of the first, second and third input when possibly several chargers are connected simultaneously, optionally in the connection between the respective input II; 12; 13 and the node K a diode D1; D2; D3 are included.

4

A first, second and third connector C1, C2, C3 are connected to the first, second and third inputs II, 12,13, respectively.

An output connector C4 can be connected to the output U1.

The first, second and third input II, 12, 13 are adapted to connect a charger 01, 02, 03 associated with a first, second and third mobile telephone (not shown). The first, second, third connector C1, C2, C3 is here arranged as a specific socket for a respective connecting plug of the charger Ol; 02; 03.

The output connector C4 at the output U1 is adapted for coupling to a specific electrical input port (not shown) of the user's specific mobile telephone, wherein a supply voltage can be applied to the battery of the mobile telephone via the input port during use.

In a further embodiment, the output U1 is arranged such that the output connector C4 can be releasably coupled to the output U1. In that case the connector C4 may comprise a coupling piece, so that the connector C4 can be exchanged with another coupling piece C4 "which is suitable for coupling to the electrical input port of another specific mobile telephone.

Advantageously, by using a coupling piece C4; C4 ’on the output UI ensures that the circuit can be easily adapted to a specific mobile telephone with a specific electrical connection for the charger.

As outlined above, the power supply voltage that a specific charger generates may deviate from the power supply voltage applied to the mobile phone to be charged.

It appears that despite differences in the supply voltage value of mobile telephones of different types and / or brands, the battery used in the telephones is very often suitable for charging at a charging voltage other than the one set (or prescribed by the manufacturer of the mobile telephone) ) supply voltage value. This general charging voltage can be applied to the power supply connection of the mobile telephone without damaging the internal circuits of the mobile telephone.

The circuit according to the invention is arranged to provide a general charging voltage V to the output UI.

5

With many mobile phones the value of the general charging voltage appears to be 5.5 V.

In the present invention, a choice has been made for providing a number of connectors C1, C2, C3 for chargers of specific mobile telephones, of which it is known that they are available to a limited extent on the market, because of course the greatest possible availability of chargers can be obtained.

Some of the available chargers will provide a higher voltage than the general charging voltage, while other chargers will provide a lower voltage.

The brand and / or type of specific connector and the supply voltage of the associated charger have a known relationship, that is to say, a mobile phone with a specific connector includes a charger that supplies a known voltage.

On the basis of that fact, the circuit according to the invention can be arranged such that the voltage on the input II; 12 is adapted to the general charging voltage to be supplied. The above-mentioned voltage regulator S1 serves for this purpose; S2.

For example, the first connector C1 on the first input II belongs to a charger 01 which supplies an input voltage VI that is higher than the desired general charging voltage V. The voltage regulator S1 is then arranged to lower the input voltage VI to the general charging voltage V.

For example, the second connector C2 on the second input 12 belongs to a second charger 02 which outputs a second input voltage V2 that is lower than the desired general charging voltage V. The second voltage regulator S2 is then adapted to increase the second input voltage V2 to the general charging voltage V.

The third connector C3 on the third input 13, for example, belongs to a third charger 03 which supplies a third input voltage V3 which is substantially equal to the desired general charging voltage V. The third input voltage V3 can then be directly connected to the output U1.

It is noted that in the example above three inputs are shown, but it is possible that more inputs are present.

Figure 2 shows schematically a second embodiment of the circuit.

Reference numerals in Figure 2 which are the same as in Figure 1 always refer to similar elements as described in Figure 1.

6

The circuit P2 in the second embodiment is largely the same as the circuit P of the first embodiment. For that reason, a description of the same parts is omitted and only the differences are described here.

In the second embodiment, the circuit P2 is provided with a further connection B, which is also connected to the output U1 via the node K.

Further connection B is adapted for connecting a battery or a separate battery. The battery or accumulator is arranged for supplying the general charging voltage of, for example, 5.5 V.

The connection between the further terminal B and the node K10 can also be provided with a diode D4 to protect the circuit P2 against damage with simultaneously connected chargers.

Advantageously, by providing the further connection B, it is achieved that in cases where no usable charger is available (or when the fixed electricity network is not available) the mobile telephone can nevertheless be supplied with voltage. In the second embodiment, the circuit can function as a charger for the battery of the mobile telephone, but also as a source for supplying power to the mobile telephone for direct use.

Figures 3 and 4 show perspective views of first and second configurations in which the circuit P; P2 according to the present invention is included.

As shown in Figure 3, the first shape F1 has a housing with a substantially circular shape. The circuit P according to the first embodiment is included in this housing. The housing has a size with a diameter of approximately 5 cm and a height of approximately 1 cm. Due to this small size, the circuit can easily be taken by the user.

The connection of the output U1 and the connectors (connections) C1, C2, C3 for chargers Ol, 02, 03 are included in the circumference surface of the housing, the connectors and the connection of the output being situated at substantially the same mutual distance along the circumference.

In addition to the connection U1, the output connector C4 is shown which can be releasably connected to UI. Output connector C4 can be one of a set of output connectors for a set of mobile telephones each equipped with a different input port contra connector.

7

The output connector C4 can be a substantially rod-shaped plug-in element for a pin / bus connection, but can also comprise a wire piece between the connector C4 and the output U1.

As shown in Figure 4, a second shape F2 also has a housing 5 with a substantially round shape. The circuit P2 according to the second embodiment is included in this housing.

A space (not shown) is provided in the housing F2 for receiving the battery. One of the surfaces of the housing is provided with a shut-off valve G which can provide access to the space for the battery.

In another embodiment, the housing is substantially rectangular, wherein in one or more side faces of the housing the connection of the output U1 and the connectors (connections) C1, C2, C3 for chargers 01, 02.03 are included.

Figure 5 shows schematically a third embodiment P3 of the circuit according to the present invention.

In Figure 5, the same reference numerals as used in the preceding Figures 1-4 refer to corresponding parts.

In the third embodiment, the inputs II, 12, 14 are connected to a first input A1 of a voltage converter S3.

The first, second and third connectors 20 are connected to each input II, 12, 14, respectively C1, C2, C3.

Each input II, 12, 14 is adapted to connect a charger 01, 02, 04 associated with a first, second and third mobile telephone or portable electronic device (not shown). The first, second, third connector C1, C2, C3 is here arranged as a specific socket for a respective connection plug of the charger Ol; 02; 04.

Charger 01 supplies a supply voltage VI, charger 02 supplies a supply voltage V2 and charger 04 supplies a supply voltage V4.

Via an output A2 the voltage converter S3 is connected to an input A4 of a voltage comparator S4. An output A5 of the voltage comparator S4 is connected to terminal K of the output U1.

A second output A6 of the voltage comparator S4 is connected to a second input A3 of the voltage converter S3.

8

The voltage converter S3 is adapted to convert an input voltage V1, V2 or V3 from input II, 12 and 14 respectively to the general charging voltage V as an output voltage at the output U1.

The voltage converter S3 is then arranged during use to control the output voltage 5 V to a constant value by feeding back a voltage Vu applied to the output A2 by means of the voltage comparator S4.

The voltage comparator S4 is adapted to determine the value of the voltage Vu applied to the output A2 and to compare it with the desired general charging voltage V. Based on the comparison, a feedback signal Vt 10 is generated. The feedback signal Vt from the voltage comparator S4 is supplied to the second input of the voltage converter S3.

The determination of the value of the voltage Vu applied to the output A2 of the voltage converter S3 can, for example, be measured by measuring the voltage drop across a resistor, as will be explained in more detail in Figure 6.

The voltage converter S3 is adapted to change the output voltage Vu at the output A2 on the basis of the received feedback signal Vt.

A diode D is included in the connection of each input II, 12, 14 with the first input A1 of the voltage converter S3 in order to prevent interactions of the inputs.

Figure 6 shows in detail an embodiment of the voltage comparator S4 of Figure 5. The voltage comparator S4 comprises a first, second, third, fourth, fifth, and sixth resistor R1, R2, R3, R4, R5, R6, and a comparator CP .

The first resistor R1 is a measuring resistor which is connected to a first terminal A7 at the output of the voltage converter S3 and to a second terminal A8 at the node K of the output U1. A voltage drop is determined over the measuring resistor (first resistor R1).

In a first branch, the second and third resistors R2 and R3 are connected in series with the first terminal A7 of the first resistor R1. In a second branch, the fourth and fifth resistors R4 and R5 are connected in series with the second terminal A8 of the first resistor R1. The third resistor R3 and fifth resistor are furthermore each connected to a first terminal of the sixth resistor R6 which is connected to ground with a second terminal.

9

The comparator CP is connected with a first input CP1 to a connection N1 between the second and third resistor R2, R3, and is connected to a second input CP2 to a connection N2 between the fourth and fifth resistor R4, R5. An output CP3 of the comparator CP is connected to the second input A3 of the voltage converter S3 for supplying the feedback signal Vt to the voltage converter S3 during use.

By choosing a suitable resistor value for each of the first, second, third, fourth, fifth, sixth resistor R1, R2, R3, R4, R5, R6, the voltage comparator S4 of Figure 6 is able to determine whether the output voltage of the voltage converter S3 essentially corresponds to the desired general charging voltage V. On the basis of the feedback signal Vt from the comparator CP, the output voltage Vu can be controlled by the voltage converter S3.

Via the connection N1 between the second and third resistor R2, R3, a first measuring voltage Vml is tapped on the side of terminal A7 of measuring resistor R1.

Via the connection N2 between the fourth and fifth resistor R4, R5, a second measuring voltage Vm2 is tapped on the side of terminal A8 of measuring resistor R1. By suitable choice of the resistance values R1, R2, R3, R4, R5, R6, it is possible to determine from the difference of the first and second measuring voltage Vml, Vm2 whether the output voltage Vu has the desired value for applying the general charging voltage V to the output U1 reach. By feedback of the feedback signal Vt from the comparator Cp, the voltage converter S3 is able to adjust the output voltage.

In one embodiment, the voltage converter S3 is adapted to convert input voltages between approximately 3 Volts and approximately 12 Volts to a general charging voltage V of approximately 5.5 Volts.

A DC-DC converter suitable as a voltage converter S3 is, for example, of the MC34063A type.

Figure 7 shows a fourth embodiment P4 of the circuit for a charger.

In Figure 7, the same reference numerals as used in the preceding Figures 1-6 refer to corresponding parts.

In the fourth embodiment the circuit largely corresponds to the third embodiment as shown in Fig. 5, but the circuit further comprises a rechargeable battery, a battery charging circuit LC and a battery switching circuit BS.

10

The battery charging circuit LC is connected to a connection between the inputs II, 12, 14 and the first input A1 of the voltage converter S3 with a first connection L1.

Furthermore, the battery charging circuit LC is connected to a second connection L2 to a connection L3 of the rechargeable battery. A second connection L4 of the battery is connected to earth. The second terminal L4 of the battery has a polarity that is opposite to the polarity of the first terminal L1 of the battery.

Furthermore, a first connection L5 of the battery enabling circuit BS is connected to the battery charging circuit LC. A second terminal L6 of the battery enabling circuit BS 10 is connected to the first terminal L3 of the battery.

In this fourth embodiment, the circuit P4 is able to not only generate a general charging voltage V at the output U1, but also to charge a rechargeable battery whether or not simultaneously.

Via the battery charging circuit LC, the battery can be connected to one of the 15 on chargers Ol, 02, 04 for charging the battery.

Via the battery enable circuit BS, the battery can be connected to the voltage converter S3 for supplying battery voltage as the supply voltage for the voltage converter S3.

As a result, the rechargeable battery in this circuit can advantageously be used as an additional power supply for generating the general charging voltage V at the output U1, in case no charger would be available for connection to one of the connectors C1, C2, C3.

It is also possible to charge the rechargeable battery of the circuit P4 without a portable electronic device being connected to the output U1.

The embodiments of figures 5, 6 and 7 can be realized in the housings as shown in figures 3 and 4. The housing F2 can for instance contain a rechargeable battery instead of the exchangeable battery B. The closing flap G for accessing the space in which battery B can be accommodated in the housing can possibly be omitted in the event that the battery is located in the housing. The battery is then located behind a fixed wall of the housing.

Other alternatives and equivalent embodiments of the present invention are conceivable within the inventive concept, as will be apparent to those skilled in the art. The inventive concept is only limited by the appended claims.

Claims (19)

A circuit (P; P2; P3; P4) for charging a battery of a portable electronic device, comprising at least two inputs (II, 12; II, 12,14) and an output (U1), the inputs are arranged for connecting a charger (Ol, 02; Ol, 02, 04) and the output is adapted for coupling to an electrical input port of the portable electronic device which electrical input port is suitable for receiving a supply voltage for the battery; wherein each input (II, 12; II, 12,14) contacts a connection point (K) of the output via a connection, and wherein at least one connection a voltage converter (S1; S2; S3) is included to use a supply voltage (VI, V2; VI, V2, V4) applied by the charger (Ol, 02; Ol, 02, 04) to the respective input to a general charging voltage (V) at the output (U1). Circuit (P; P2) according to claim 1, wherein a first voltage converter (S1) is included in the connection of the first input (II) to the connection point (K). 3. Circuit (P; P2) according to claim 1 or 2, wherein a second voltage converter (S2) is included in the connection of the second input (12) to the connection point (K). Circuit (P; P2) according to one of the preceding claims, wherein the circuit comprises a further input (13) for a further charger (03) which contacts a connection point (K) of the output via a further connection. 5 C4 ’) includes a releasable connector. 5. Circuit (P; P2; P3; P4) according to one of the preceding claims, wherein each of the inputs (II, 12,13; II, 12,14) is provided with a connector (C1; C2; C3) which is arranged as a specific socket for a connection plug of the respective charger (01, 02, 03; Ol, 02, 04). The circuit (P; P2; P3; P4) according to any of the preceding claims, wherein the circuit (P; P2) comprises an output connector (C4; C4 ') which is adapted for coupling to the electrical input port of the portable electronic device . The circuit (P; P2; P3; P4) according to claim 6, wherein the output connector (C4; The circuit (P3; P4) according to claim 1, wherein the circuit is provided with a voltage converter (S3) in order to use the supply voltage (VI; V2; V4) applied to the input by the charger (01; 02; 04) to put in the general charging voltage (V) on the output (UI). The circuit (P3; P4) according to claim 8, wherein the circuit further comprises a voltage comparator (S4) for comparing the value of the voltage (Vu) output from the voltage converter (S3) with a desired value of the general charging voltage (V) to the output (UI). 10. A circuit (P3; P4) according to claim 9, wherein an output (A6) of the voltage comparator (S4) is connected to a second input (A3) of the voltage converter (S3); the voltage comparator is arranged to generate a feedback signal (Vt) on the basis of the comparison of the voltage (Vu) output from the voltage converter (S3) with the desired value of the general charging voltage (V) and to send the feedback signal to the second input of the voltage converter, and wherein the voltage converter is adapted to adjust the output voltage in response to the received feedback signal. The circuit (P4) according to any of claims 1, 8, 9 or 10, wherein the circuit 25 is a battery charging circuit (LC), a battery switching circuit (BS) and a first battery connection (L3) for a rechargeable battery; wherein a first connection (L1) of the battery charging circuit is connected to the inputs (II, 12.14) and a second connection (L2) of the battery charging circuit to the first battery connection; wherein a first connection (L5) of the battery enable circuit (BS) is connected to the inputs (II, 12.14) and a second connection (L6) of the battery enable circuit (BS) is connected to the first battery connection ; wherein a second battery connection (L4) is connected to ground, and wherein the battery charging circuit is adapted to provide to its second connection (L2) a charging voltage for a battery in case a charger (01; 02; 04) is connected to one of the inputs, and the battery enable circuit is adapted to connect the first battery connection to the voltage converter (S3) in case a charger is not connected to any of the inputs 10. The circuit (P4) of claim 11, wherein the circuit comprises a rechargeable battery fixedly connected to the first and second battery connection (L3; L4). 13. A circuit (P; P2; P3; P4) according to any of claims 6-7, wherein the output connector (C4; C4 ') is one of a plurality of output connectors for a plurality of portable electronic devices each having a different electrical input port connector is equipped. The circuit (P; P2; P3) according to claim 1, wherein the circuit comprises a further connector (B) which is connected to the connection point (K) of the output (U1) and which further connector is adapted to connect a 20 battery or a separate battery. The circuit (P; P2) according to any of the preceding claims, wherein the portable electronic device belongs to a class of: - mobile telephones; - portable music players; 25. electronic calendars, or - portable computers. A housing (FI; F2) for a circuit (P; P2; P3; P4) according to any of claims 1-14, wherein the housing has a substantially round shape and wherein in a peripheral surface of the housing the connection of the output and the connectors are included. A housing (FI; F2) for a circuit (P; P2; P3) according to claim 16, wherein the housing (F2) comprises a space for receiving the battery battery, and wherein one of the faces of the housing is equipped with a shut-off valve (G) for this space. A housing (FI; F2) for a circuit (P4) according to claim 16, wherein the housing (F2) comprises a space for receiving the rechargeable battery. 19. Charger (01; 02; 03; 04) provided with a circuit according to one of the preceding claims.