NL1028797C2 - Rechargeable power supply. - Google Patents

Description

Rechargeable power supply

The invention relates to a rechargeable power supply suitable for use in or in combination with a battery-powered device.

Battery-powered devices are available today in a wide variety. As a pervasive example, the mobile phone can be mentioned, which on the one hand provides great ease of use, but on the other hand can cause annoyance to the user for various reasons.

Annoyance arises with humming when the device's battery is almost empty and one or more calls are made. Even more annoyance occurs when the battery no longer fulfills its essential function during a call to keep the mobile phone operational.

As already noted above, the mobile telephone is only an example. Other devices are also battery powered, whereby the problem of running out of the battery at an awkward moment can also occur to a greater or lesser extent.

The problem just mentioned and the annoyance that arises with the battery running out prematurely is exacerbated by the fact that recharging the battery takes some time. Time that modern man thinks he does not have, so that the recharging of the battery is awaited with patience.

The object of the invention is to provide a rechargeable power supply that is rapidly rechargeable and with which the above-mentioned annoyances can be suppressed.

To that end, the rechargeable power supply according to the invention is characterized in that it comprises at least one super-capacitor.

It has been found that a rechargeable power supply built around one or more of such super capacitors can be provided with a usable energy level in a charging time of approximately 5-120 seconds, so that in the example of the mobile telephone an additional talk time of approximately 30 minutes.

The super-capacitor referred to in the present invention comprises an electrolyte and electrodes wherein the electrodes are selected from the group comprising activated carbon powders, carbon nanocanals, metal oxides, composite materials with carbon (such as polypyrrole) and conductive polymers. Such supercapacitors are known from the literature, see for example the article "Development 10 of new supercapacitor electrodes based on carbon nanotubes" by E. Frackowiak et al., Published in Polish Journal of Chemistry, 78, p. 1345-1356 (2004).

In a further aspect of the invention, the rechargeable power supply is characterized in that it comprises at least a first and a second DC-DC converter which are connected in series, the first DC-DC converter being connected to the super capacitor and connected to a super capacitor. the device to be supplied can be connected to the output of the second DC-DC converter.

With this measure the problem is overcome that during use the super-capacitor has the property that when the super-capacitor becomes empty, the voltage across the super-capacitor decreases. This results in the voltage falling below the minimum required voltage required by the device to be supplied. The measure just mentioned ensures that the super capacitor can feed this device longer so that the effective charge of the super capacitor is increased. The first DC-DC converter achieves a reduced output voltage for this purpose, while the second DC-DC converter provides an output voltage that is above the minimum voltage of the device to be supplied.

In yet another aspect of the invention, the rechargeable power supply is characterized in that a battery is slowly discharged relative to the super-capacitor and is directly or indirectly connected to the super-capacitor.

This resolves the problem that the super capacitor, when not being used, loses its effective charge in the course of a few days due to leakage current. In this proposed embodiment, the super capacitor can deliver its effective charge to the battery connected in parallel with it, so that the effective charge remains available even during a longer standstill period.

The invention is also embodied in a power supply unit for a rechargeable power supply as explained above, which is provided with an electronic circuit in which the super capacitor can be accommodated and which can be connected to an external power supply, for charging the super-capacitor.

By means of the electronic circuit, the super capacitor can be kept within the current and voltage limits that are required to prevent undesired damage to the super capacitor.

To this end, it is advantageous that the electronic circuit comprises control electronics for controlling the electronic circuit in dependence on a charge level of the super capacitor.

A suitable embodiment of this power supply unit 20 for the rechargeable power supply according to the invention is further characterized in that the electronic circuit comprises a coil and an electronic switch connected in series therewith, and that at an electrical connection point between the coil and the electronic switch, the super capacitor 25 can be connected.

The invention will be further elucidated hereinbelow on the basis of some non-limiting exemplary embodiments of a rechargeable power supply according to the invention according to the following claims.

In the drawing: - figure 1 shows an electrical diagram of a DC-supplied power supply unit for a rechargeable power supply according to the invention, - figure 2 shows an electrical diagram of an alternating current; A power-supplied power supply unit for a rechargeable power supply according to the invention, and FIG. 3 an electrical diagram of a preferred embodiment of a rechargeable power supply according to the invention.

Identical reference numerals 5 used in the figures refer to the same parts.

Figure 1 shows a power supply unit for a rechargeable power supply that can be connected to a DC voltage V-supply for charging a super capacitor 1 connected to this power supply unit.

Such a super capacitor 1 is built in a housing in which an electrolyte is included and electrodes.

The electrodes are selected from the group consisting of activated carbon powders, carbon nano-channels, metal oxides, composite materials with carbon, and conductive polymers.

Figure 1 shows that the super capacitor 1 is incorporated in an electronic circuit which can be connected to said external DC supply V-supply of 10-30 volts for charging the super capacitor 1. The electronic circuit further comprises control electronics 2 for controlling the electronic circuit in dependence on a charge level of the super capacitor 1 as determined with the measuring bridges 3 and 4. Depending on the voltage levels measured at the location of these measuring bridges 3 and 4, the control electronics 2 responds by controlling driving an electronic switch 5 placed in series with a coil 6 which in turn is connected to the DC power supply v-supply.

The above-mentioned super capacitor 1 is connected to the electrical connection point 7 between the coil 6 and the electronic switch 5 via a low-loss diode 8.

The control electronics 2 are arranged to come to a rapid charge of this capacitor without damage to the super capacitor 1 which is to be avoided, whereby the energy is obtained from the coil 6 connected to the supply voltage V-supply 35.

The circuit of Figure 1 works as follows.

The power supply is connected to a direct voltage in the range of 10-30 volts which can provide sufficient power 1028797 to charge the super capacitor 1 within a desired time.

The supply voltage V-supply is loaded with a capacitor 11 which ensures that any current peaks 5 exert little influence on the supply voltage V-supply during charging.

Connected in parallel to the super capacitor 1 is a zener diode 12 which serves as a surge protector. Also connected in parallel therewith is a capacitor 13 which absorbs 10 transition effects which are the result of coupling and disconnecting the super capacitor 1. Namely, this super capacitor 1 is namely connected to the circuit by means of a (long) cable.

The control electronics 2 provides the charging process that starts when it has been measured that the supply voltage V-supply is more than 10 volts and that the super capacitor 1 has a lower than its maximum operating voltage. When these criteria are met, the control electronics 2 ensures that electronic switch 5 which is designed as a mosfet is opened, as a result of which coil 6 becomes current-carrying. The current through coil 6 is measured with a measuring resistor 14. When this current reaches its maximum value, measured with the aid of resistor 14, the control electronics 2 close switch 5 again so that a voltage equal to the voltage across the super capacitor 1 minus the voltage across the Shottky diode 8. The current path blocked by the closing of the switch 5 ensures that the current now charges the super capacitor 1 via said diode 8. In this process, the current gradually decreases. When this current and the corresponding voltage across the coil 6 has decreased sufficiently, the charging cycle is finished and a repetition of the charging cycle can take place if desired.

Figure 2 shows very diagrammatically the electrical diagram of an alternating voltage-supplied power supply unit according to the invention. The supply voltage Vcc is rectified via a diode 9 and charges a capacitor 10. The current used for charging the super capacitor 1 is taken from this capacitor 10.

For charging the super capacitor 1, just as in the case of the circuit 5 shown in Figure 1, an electronic switch 5 and a coil 6 placed in series therewith are provided. Furthermore, control electronics 2 are provided for depending on the charging cycle of the super capacitor. 1 controlling the electronic switch 5 so that it is alternately switched on and off.

Consequently, the current flowing through coil 6 is also alternately switched on and off, as a result of which the current-conserving properties of the coil 6 can charge the super-capacitor 1.

It is clear to a person skilled in the art that within the scope of the invention the circuits shown in Figs. 1 and 2 can be changed without thereby departing from the inventive concept as set forth in the following claims.

The scope of protection which is due to the invention is therefore only determined by the following claims, without this being deemed to be limited to the specific exemplary embodiments given above for the purpose of explaining these claims.

Finally, Figure 3 shows the rechargeable power supply according to the invention in a preferred configuration.

The rechargeable power supply shown in Figure 3 is again essentially formed by the super capacitor 1 to which preferably a first DC-DC converter 15 and a second DC-DC converter 16 are connected. The first DC-DC converter 15 and the second DC-DC converter 16 are connected in series 30.

The first DC-DC converter 15 ensures a downward conversion of the DC voltage from the super capacitor 1, while the second DC-DC converter 16 provides an up-conversion of the DC voltage to ensure that the output voltage of this second DC-DC converter 16 is at least the minimum voltage that the device to be connected to the power supply requires.

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Figure 3 further shows that a battery 17 connected in parallel with the super capacitor 1 can be placed between the first DC-DC converter 15 and the second DC-DC converter 16. It can hereby be ensured that the relatively large leakage current of the super capacitor 1 does not have a negative effect on the availability of energy at the output clay conductors of the second DC-DC converter 16 when the rechargeable power supply according to the invention has been out of use for a considerable time.

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Claims (8)

Rechargeable power supply suitable for use in a battery-powered device, characterized in that it comprises at least one super-capacitor. Rechargeable power supply according to claim 1, characterized in that the super capacitor comprises an electrolyte and electrodes, the electrodes being selected from the group consisting of activated carbon powders, carbon nanocannals, metal oxides, composite materials with carbon, and conductive polymers. Rechargeable power supply according to any one of claims 1 to 2, characterized in that the power supply comprises at least a first and a second DC-DC converter which are connected in series, and wherein the first DC-DC converter is connected to during operation the super capacitor and that the device can be connected to an output of the second DC-DC converter. Rechargeable power supply according to any one of claims 1 to 3, characterized in that a battery is slowly discharged relative to the super capacitor and is directly or indirectly connected to the super capacitor. 5. A power supply unit for a rechargeable power supply as claimed in any one of claims 1-3, characterized in that it is provided with an electronic circuit in which the super capacitor can be accommodated and which can be connected to an external power supply, for charging the super capacitor. A power supply unit according to claim 5, characterized in that the electronic circuit comprises control electronics for controlling the electronic circuit in dependence on a charge level of the super capacitor. 7. Power supply unit as claimed in claim 5 or 6, characterized in that the electronic circuit comprises a coil and an electronic switch connected in series therewith, and that the super capacitor can be connected to an electrical connection point between the coil and the electronic switch. 1028797 8. Use of a super capacitor as a rechargeable power supply or as part thereof. 1028797