FR2883428A1 - Cell or battery recharging method for e.g. portable telephone, involves generating periodic signal by control block of charger via amplifier to excite LC series circuit to emit magnetic field, where circuit includes antenna and capacitance - Google Patents

Abstract

The method involves generating a periodic excitation signal by a control block of charger via an amplifier to excite a LC series circuit to emit an magnetic field, where the circuit has an antenna and an capacitance. The cell or battery (22) of an electronic equipment (20) is closed on a LC parallel circuit by diodes. The equipment is brought closer to the charger at sufficient distance so that the field radiated by an antenna of the series circuit is captured by an antenna (9) of the parallel circuit. A current induced in the parallel circuit is rectified and generated to recharge the cell.

Description

METHOD FOR RECHARGING A BATTERY OR BATTERY OF AN EQUIPMENT

  ELECTRONICS USING A CHARGER AND EQUIPMENT

  ELECTRONICS SUITABLE FOR SUCH A METHOD

  The invention relates to a method for recharging a battery or battery of electronic equipment using a charger.

  All portable electronic equipment uses to operate a battery. During intense use, the battery of these electronic equipment needs to be recharged. A traditional charger consisting of a transformer, a cable and a connector makes it possible to connect to these portable electronic equipment in order to recharge the battery. There are situations where the charger is not available, the battery then comes to discharge, making in such conditions these portable electronic equipment not usable. It should also be noted that it seems difficult to find chargers of portable electronic equipment compatible with each other unless the portable electronic equipment is of the same brand and the same range of products. Indeed, the chargers differ from each other according to the brands of the manufacturers and often even from one product to another of the same manufacturer.

  The object of the invention is to provide users of portable electronic equipment, a universal energy transfer method thus reloading the batteries of portable electronic equipment from a fixed or non-portable electronic equipment without the need of a conventional charger or to transfer some of the energy of portable electronic equipment to other portable electronic equipment in discharged battery conditions.

  This universal energy transfer method must make it possible to operate regardless of the commercial brand of these portable or non-portable electronic equipment as well as their various forms.

  For this purpose, the subject of the invention is a method for charging a battery or battery of electronic equipment using a charger, comprising the following steps: using a control block installed in the charger and powered by a power source, generating a periodic excitation signal, for example of frequency equal to 125 kHz or 13.56 MHz, through an amplifier, to excite a closed series LC circuit on the control block and resonant at the frequency of the excitation signal comprising in series a capacitance and an antenna radiating a magnetic field having the same frequency as that of the excitation signal; by means of a parallel LC circuit installed in the electronic equipment and resonating at the same frequency as that of the series LC circuit, comprising in parallel a capacitance and an antenna, closing the battery or battery on the parallel LC circuit by intermediate of a circuit rectifying an induced current in the parallel LC circuit; and - bringing the electronic equipment closer to the charger at a distance sufficient for the magnetic field radiated by the antenna of the loader LC serial circuit to be picked up by the antenna of the parallel LC circuit of the electronic equipment and to induce a current in this circuit rectified by the rectifier circuit to recharge the battery or battery of the electronic equipment.

  In one embodiment of the invention, the charger is a second electronic equipment provided with a battery or battery supplying the control block generating the periodic excitation signal.

  The invention extends to an electronic equipment provided with a battery or battery intended for the implementation of a method according to the invention, characterized in that it comprises a parallel LC circuit resonant at a frequency, for example equal to 125 kHz or 13.56 MHz, comprising in parallel a capacitance and an antenna for sensing a magnetic field, closed on the battery or battery by means of a circuit that rectifies a current induced in the parallel LC circuit.

  The invention also extends to an electronic equipment acting as charger, characterized in that it comprises a control unit powered by the battery or battery to generate a periodic excitation signal, for example of frequency equal to 125 kHz or 13.56 MHz, via an amplifier and a closed serial LC circuit on the control block and resonant at the frequency of the excitation signal, comprising in series a capacitance and an antenna for radiating a magnetic field of same frequency as that of the excitation signal.

  In a preferred embodiment of the invention, the same electronic equipment is provided to function as a charger or as electronic equipment which must be recharged battery or battery. Thus, the charger or the electronic equipment is characterized in that it comprises a control unit powered by the battery or battery to generate a periodic excitation signal, for example of frequency equal to 125 kHz or 13.56 MHz, via an amplifier, a serial LC circuit, comprising in series a capacitance and an antenna for radiating a magnetic field of the same frequency as that of the excitation signal, a parallel LC circuit comprising in parallel a capacitance and an antenna in order to pick up a magnetic field, the two series LC and parallel LC circuits resonant at the frequency of the excitation signal, and a switch controlled by a control block between two positions, a so-called closing position in which the switch closes the circuit Parallel LC on the battery or battery via a current rectifier circuit, and the other said opening in which the switch is open, the control block comma the amplifier is respectively turned off at the same time as it controls the switch in the closed position and activated at the same time as it controls the switch 27 in the open position.

  In a particular embodiment, this charger or electronic equipment comprises a contactor mounted in parallel with the switch and controlled by a mechanical means independent of the battery or battery between two positions, one said load in which the contactor closes the parallel LC circuit on the battery or battery and the other said rest in which the contactor is open.

  Preferably, the contactor is controlled by a pushbutton or a movable drawer.

  Other advantageous features of the invention are described below with the aid of several embodiments of the invention illustrated by the figures.

  Figure 1 is a diagram of the onboard electronics describing the energy output of a fixed charger to a portable electronic equipment with a battery or battery.

  Figure 2 is a diagram of the onboard electronics describing the receipt of energy by the portable electronic equipment from the fixed charger.

  Figure 3 is a diagram of the onboard electronics of a first portable electronic equipment for the transmission or reception of energy, the electronic equipment being in transmission mode.

  FIG. 4 is a diagram of the on-board electronics of a second portable electronic equipment which again makes it possible to transmit or receive energy, the electronic equipment being in receiving mode.

  Figure 5 shows two models of mobile phones in short-range magnetic coupling to recharge the battery or battery of one with the aid of the other.

  Figure 6 shows a mobile phone model with an integrated radio frequency antenna, for example 125 kHz.

  Figure 7 shows a model of mobile phone with an integrated radio frequency antenna for example of 13.56 MHz.

  Figure 8 shows a model of a mobile phone and a laptop in short-range magnetic coupling to recharge the cell phone battery or battery using the laptop.

  Figure 9 shows a model of mobile phone and a charger powered by the battery of a motor vehicle.

  Figure 10 shows a mobile phone model and a mains-powered charger in short-range magnetic coupling to charge the mobile phone with the charger.

  The invention uses a radio frequency antenna integrated in each portable electronic equipment to transfer a portion of the energy stored in the battery of portable electronic equipment to other portable electronic equipment under discharged battery conditions and vice versa.

  The radio frequency antenna integrated in the electronic equipment acting as a charger generates a minimum radiated magnetic field strength thereby enabling the radio frequency antenna integrated in the portable electronic equipment to receive a maximum voltage induced by the condition. short-range magnetic coupling.

  The radio frequency antenna integrated in portable, fixed or non-portable electronic equipment is preferably made using frequencies in the standard ISM bands (frequency bands used in industrial, scientific or medical fields) of 125 kHz or 13.56 MHz. MHz. Other frequencies in the standard authorized bands are also suitable.

  The method according to the invention uses a charger and electronic equipment whose electrical circuits are shown in FIGS. 1 and 2. These figures show the various electronic elements involved in the transfer of energy stored in the battery of a device. electronics acting as a charger to portable electronic equipment in discharged battery conditions.

  The charger illustrated in Figure 1 comprises the following electronic elements. A control block 1 has the function of generating a frequency signal in the ISM band by an amplifier 3 to ensure resonance of an electronically tuned LC-series 5.7 circuit. The inductor 5 represents the antenna element and the electronic element 7 represents a capacitance. The LC-series tuned electronic circuit generates a minimum radiated magnetic field strength in the antenna 5 to develop a maximum voltage induced in the antenna 9 of the electronic equipment illustrated in FIG. 2 connected in parallel with a capacitor 11, in the condition of a short-range magnetic coupling. A resistor 13 makes it possible to adjust an amplification factor of the radiated magnetic field. Lines 15 and 17 supply the electronic elements of the control block 1.

  In order to receive the energy emitted by the charger, the electronic equipment illustrated in FIG. 2 is configured as a receiver. The tuned electronic circuit LC here is a circuit in parallel. The inductor 9 represents the antenna element and the electronic element 11 represents a capacitance. The voltage induced in the tuned antenna 9 is rectified by a diode bridge 19 in order to supply the discharged battery 21.

  It should be noted that the energy transfer method is also applicable without the need for a battery or battery specific to this transfer. In this case, a capacitive element is added to the portable electronic equipment, connected in parallel with the power supply of their respective batteries.

  In a preferred embodiment of the invention, the same electronic equipment is provided to function as a charger or as electronic equipment which must be recharged battery or battery. This embodiment is presented in FIGS. 3 and 4. These figures express, by thick lines, the various electronic elements solicited in the transfer of energy stored in the battery of portable electronic equipment, FIG. 3, to another electronic equipment. portable, figure 4, being in discharged battery conditions. It should be noted that these figures show a complete reversibility of energy transfer.

  In the electronic equipment illustrated in FIGS. 3 and 4, the same references as those used in FIGS. 1 and 2 denote the same electronic elements. In each of the electronic equipment, FIGS. 3 and 4, a switch 27 is controlled by the control block 1 between two positions, a so-called closing position in which the switch 27 closes the parallel LC circuit on the battery or battery by the intermediate of a current rectifier circuit, and the other said opening in which the switch 27 is open. In order to select the transmission mode, FIG. 3 opens the switch 27 using the control block 1. Similarly, to select the receive mode, FIG. 4, the switch 27 is closed on the parallel LC circuit.

  In other words, a control signal closes the switch 27 so as to activate the LC-parallel tuned electronic circuit 9, 11 and at the same time deactivates the amplifier 3.

  The selection of the energy transfer mode is thus activated via the control signal. This control signal controls the closing or opening of the switch 27 to activate or deactivate the LC-parallel tuned electronic circuit 9, 11 according to the selection of the mode respectively in reception or transmission which determines the direction of the energy transfer. The control block 1 controls the amplifier 3 to turn it off at the same time as it controls the switch 27 in the closed position and to activate it at the same time as it controls the switch 27 in the open position.

  In the case of a flat battery, the control block 1 is not powered. In this case, to receive energy from a portable equipment acting as a charger, a switch 29 is connected in parallel with the switch 27 and is controlled by a mechanical means 31 independent of the battery or battery between two positions, one said load in which the switch 29 closes the LC parallel circuit on the battery or battery and the other said rest in which the switch 29 is open. The contactor 29 is thus activated by a specific manual mechanical action outside the control block 1. The switch 27 is switched to the closed position by the control signal as soon as the battery or battery is sufficiently recharged to power the control block 1 The lines supply the electronic elements of the block. Preferably, the switch 29 is controlled by a pushbutton for example in the form of a key of the electronic equipment accessible to a user.

  The on-board electronic implementation of the electronic equipment according to the invention allows portable electronic equipment to easily read all kinds of transponders.

  FIGS. 1 and 2 describe an electronic implementation of energy transmission from fixed or non-portable electronic equipment to portable electronic equipment. Figures 3 and 4 describe an electronic implementation of power transmission and data information transfer from portable electronic equipment to other portable electronic equipment.

  The antennas 5, 9 denoted in FIGS. 3 and 4 and the antennas in FIGS. 1 and 2 may be made on flexible printed supports (plastic, etc.) so as to minimize the bulk.

  Figure 5, two models of mobile phones 10, 20 are shown in short-range magnetic coupling condition to recharge the battery or battery 22 of one with the battery or battery 12 the other. Figure 6, a mobile phone model 20 is shown with an integrated radio frequency antenna 91 of 125 kHz. Figure 7, a mobile phone model 20 is shown with an integrated radio frequency antenna 92 of 13.56 MHz. Figure 8, a mobile phone model 20 and a laptop computer 30 are shown in short-range magnetic coupling condition to recharge the cell phone battery or battery using the battery or laptop battery. Figure 9, a mobile phone model 20 is shown with a charger powered by the battery of a motor vehicle 40. Figure 10 shows a charger 10 according to the invention for batteries of portable electronic equipment to be recharged according to the conditions described for the transfer of energy from fixed electronic equipment to portable electronic equipment. This charger 10 consists of a power outlet, a cable and a tray incorporating an antenna 91. It can easily be an integral part of an office at home, at work, in a public place, etc. ..

  The method according to the invention applies to all families of electronic equipment, regardless of their size or shape. It allows an easy implementation of the antenna thus avoiding an excessive modification of the housing of the electronic equipment. It still allows the creation of new mobile phones or portable electronic equipment without the need for an integrated mechanical connector for their power supplies.

  In the preferred embodiment of the invention, FIGS. 3 and 4, where the same electronic equipment is provided to function as a charger or as electronic equipment for recharging the battery or battery, the electronic equipment advantageously comprises a resistor 31. series with a switch 33 controlled opening or closing by the control block 1. These two elements are connected in parallel with the antenna 5 of the LC series circuit to absorb a fraction of the magnetic field captured by the antenna 9 of the parallel LC circuit when the switch is closed by the control block on the resistor and thus modulate in amplitude this magnetic field depending on the opening or closing of the switch on the resistor.

  We are here in the presence of a modulation on the electronic equipment 20 sensing the magnetic field to recharge its battery or battery 22. The control block 1 controls closing and opening the switch 33 to modulate in amplitude the magnetic field radiated by the antenna 5 of the LC series circuit of the electronic equipment 10 functioning as charger. The modulation is for example information encoded in the form of a succession of values equal to 0 or 1, indicating that the recharge of the battery or battery is complete.

  In order for the charger 10 to be sensitive and process the information coded by the modulation, it is provided with a demodulator 35 connected to the antenna 5 of the serial LC circuit to send to the control block 1 Sun signal representative of the modulation of the signal. amplitude of the magnetic field effected by the electronic equipment 20 sensing the magnetic field radiated by the antenna 5 of the serial LC circuit of the charger 10. The control block 1 of the charger terminates the generation of the periodic excitation signal when it receives the signal indicating that the charging of the battery or battery of the electronic equipment 20 is complete.

  Thus, the charging procedure of the battery 22 of the electronic equipment 20, FIG. 4, is signaled to the energy supplier equipment 10, FIG. 3, and vice versa, by a modulation of the radiated magnetic field.

  The charging procedure allows you to count the energy supplied or requested and to stop the procedure once the battery is fully recharged.

  As indicated above, the magnetic field radiated via the amplifier 3, FIG. 3, is modulated by an absorption of the magnetic field on the antenna 5 of the series LC circuit, FIG. 4, by the resistor 31 activated by the switch 33 controlled by the command of the control block 1. The amplitude modulation of the magnetic field, by the closing or opening of the switch 33, is perceived by the demodulator 35. The closing or opening of the switch 33 determines the value of logic states 0 or 1 of the transmitted information.

Claims (7)

  A method of recharging a battery (22) of electronic equipment (20) with a charger (10), comprising the following steps: i) using a control block ( 1) installed in the charger (10) and powered by a power source (12), generating a periodic excitation signal, for example of frequency equal to 125 kHz or 13.56 MHz, via a amplifier (3) for exciting a closed series LC circuit on the control block (1) and resonating at the frequency of the excitation signal, comprising in series a capacitance (7) and an antenna (5) radiating a magnetic field of the same frequency than that of the excitation signal; ii) using a parallel LC circuit installed in the electronic equipment (20) and resonant at the same frequency as that of the series LC circuit, comprising in parallel a capacitor (11) and an antenna (9), close the battery or battery (22) on the parallel LC circuit via a circuit (19) rectifying an induced current in the parallel LC circuit; and iii) bringing the electronic equipment closer to the charger at a distance sufficient for the magnetic field radiated by the antenna (5) of the charger's serial LC circuit to be picked up by the antenna (9) of the parallel LC circuit of the equipment. electronics and generates an induced current in this circuit rectified by the rectifier circuit to recharge the battery or battery (22) of the electronic equipment.   2. A method according to claim 1, characterized in that the charger (10) is a second electronic equipment provided with a battery or battery (12) supplying the control block (1) generating the periodic excitation signal.   3. Electronic equipment (20) provided with a battery or battery (22) intended to carry out a method according to claim 1, characterized in that it comprises a parallel LC circuit resonating at a frequency, for example equal to 125 kHz or 13.56 MHz, comprising in parallel a capacitance (11) and an antenna (9) for sensing a magnetic field, closed on the battery or battery (22) via a circuit (19). ) rectifying an induced current in the parallel LC circuit.   4. Electronic equipment (10) provided with a battery or battery (12) for carrying out a method according to claim 2, characterized in that it comprises a control unit 1 powered by the battery or battery (12) for generating a periodic excitation signal, for example of frequency equal to 125 kHz or 13.56 MHz, via an amplifier (3) and a closed series LC circuit on the control block (1 ) and resonant at the frequency of the excitation signal by having in series a capacitance (7) and an antenna (5) for radiating a magnetic field of the same frequency as that of the excitation signal.   5. Electronic equipment according to claim 3 or 4, characterized in that it comprises a control block (1) powered by the battery or battery (12,22) for generating a periodic excitation signal, for example frequency equal to 125 kHz or 13.56 MHz, via an amplifier (3), a serial LC circuit, comprising in series a capacitance (7) and an antenna (5) for radiating a magnetic field of the same frequency as that of the excitation signal, a parallel LC circuit comprising in parallel a capacitance (11) and an antenna (9) for sensing a magnetic field, the two series LC and parallel LC circuits resonating at the frequency of the excitation signal, and a switch (27) controlled by the control block (1) between two positions, one said closure in which the switch closes the parallel LC circuit on the battery or battery (12,22) via a circuit (19) current rectifier, and the other said opening dan the switch (27) is open, the control block (1) controlling the amplifier (3) for respectively deactivating it and controlling the switch (27) in the closed position and activating it at the same time that it controls the switch (27) in the open position.   6. Electronic equipment according to claim 5, characterized in that it comprises a contactor (29) connected in parallel with the switch (27) and controlled by a mechanical means (31) independent of the battery or battery (12, 22) between two positions, one said charge in which the contactor (29) closes the parallel circuit LC on the battery or battery (12,22) and the other said rest in which the contactor (29) is open .   7. Electronic equipment according to claim 4, 5 or 6, characterized in that it comprises in series a resistor (31) and a switch (33) controlled in opening or closing by the control block (1), mounted in parallel with the antenna (5) of the series LC circuit for absorbing a fraction of the magnetic field captured by the antenna (9) of the parallel LC circuit, when the switch (33) is closed by the control block ( 1) on the resistor (31) and thus modulate in amplitude this magnetic field as a function of the opening or closing of the switch (33) on the resistor (31) or comprises a demodulator (35) connected to the antenna (5) of the series LC circuit for sending to the control block (1) a signal representative of an amplitude modulation of the magnetic field radiated by the antenna (5) of the series LC circuit.