Classifications

• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F1/00—Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
  • G06F1/26—Power supply means, e.g. regulation thereof
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F1/00—Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
  • G06F1/16—Constructional details or arrangements
  • G06F1/1613—Constructional details or arrangements for portable computers
  • G06F1/1632—External expansion units, e.g. docking stations
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
  • H02J50/00—Circuit arrangements or systems for wireless supply or distribution of electric power
  • H02J50/10—Circuit arrangements or systems for wireless supply or distribution of electric power using inductive coupling
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
  • H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
  • H02J7/0042—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries characterised by the mechanical construction
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
  • H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
  • H02J7/0042—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries characterised by the mechanical construction
  • H02J7/0044—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries characterised by the mechanical construction specially adapted for holding portable devices containing batteries
• • H04B5/24—
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
  • H02J50/00—Circuit arrangements or systems for wireless supply or distribution of electric power
  • H02J50/005—Mechanical details of housing or structure aiming to accommodate the power transfer means, e.g. mechanical integration of coils, antennas or transducers into emitting or receiving devices

Definitions

• the present invention is directed to providing power to electrical devices.
• the present invention relates to portable electrical devices adapted to receive power inductively.
• Mobile communication devices such as computers, cellular telephones and the like, are typically powered by power cells, i.e. rechargeable electrochemical cells often also referred to as batteries.
• power cells i.e. rechargeable electrochemical cells often also referred to as batteries.
• the charger itself usually consists of a plug box containing a step-down transformer and an AC-DC converter or rectifier which is wired to a connecting plug.
• the plug box When in use, the plug box is plugged into a 120V or 240V mains socket and the connecting plug is coupled to the device.
• the wire trailing between the device and the plug box can be unsightly. Moreover, if the trailing wire is snagged or jerked the wire and connectors may be damaged, as indeed could be the socket or the wall. Furthermore, the device may be pulled to the ground.
• Chargers are bulky items to carry around. Therefore most users of compact portable equipment such as cell phones and the like do not carry chargers with them, but prefer to rely upon periodic charging, perhaps over night. Often users rely on even more infrequent charging. As a result cells often run down at inconvenient times when no charger is available.
• Hui's system a planar inductive battery charging system is designed to enable electronic devices to be recharged.
• the system includes a planar charging module having a charging surface on which a device to be recharged is placed. Within the charging module, and parallel to the charging surface, is at least one, and preferably an array of primary windings that couple energy inductively to a secondary winding within the device to be recharged.
• the invention also provides secondary modules that allow the system to be used with conventional electronic devices not formed with secondary windings.
• Hui's system provides an inductive charging platform for mobile telephones.
• Hui's system does not describe any convenient means for providing secondary windings for conventional devices. There is therefore a need for a convenient power supply for a mobile communication device and particularly for a charger, which may be conveniently retrofitted to conventional devices.
• the present invention is directed to providing a power providing system for an electrical device comprising: a secondary inductor, wired to the electrical device, for inductively coupling with a primary inductor hardwired to a power supply, wherein the secondary inductor is incorporated into an accessory of the electrical device.
• the electrical device may be selected from the group comprising: computers, mobile telephones, media players, PDAs, Walkman® s, portable CD players, dictaphones, portable DVD players and mobile communications devices.
• the accessory may be selected from the group comprising: removable casings of the electrical device, carrying cases for transporting the electrical device, straps for carrying the electrical device, carrying handles, fashion-tags, ornamental pendants, mobile danglers, skins for encasing the electrical device, stickers for adhering to the electrical device, belt-clips, neck support straps and earphone units.
• the secondary inductor comprises an electrical connector for coupling to a power jack socket such that the secondary inductor is retrofittable to the electrical device.
• the electrical connector comprises a hermaphrodite connector comprising: a male plug portion, for coupling with the power jack socket and a female socket portion for coupling to an external power source.
• the electrical device comprises a removable power pack; the power pack being connectable to the electrical device via contacts, the secondary inductor comprising an electrical connector for coupling to the contacts.
• the electrical device further comprises an electrochemical cell, and the secondary inductor is connected to the electrochemical cell via a rectifier for charging the electrochemical cell.
• the accessory comprises a USB plug for coupling to a computer such that the electrochemical cell is selectably chargeable by power drawn from the computer.
• the USB plug is wired to a data jack socket of the electrical device such that data is exchangeable between the computer and the mobile communication device.
• the power providing system further comprises an audio device having an external earphone unit, wherein the secondary inductor is incorporated into the earphone unit.
• the external earphone unit comprises at least one inductive element for inductively coupling the primary inductor to the secondary inductor.
• the inductive element comprises the secondary inductor.
• the secondary inductor may comprise a voice coil of at least one speaker of the earphone unit.
• the secondary inductor comprises at least one loop of wire.
• the loop of wire may be incorporated into a neck support strap for supporting the audio device.
• the ends of at least one wire are connected together to produce the at least one loop of wire.
• the earphone unit includes an inductive element which comprises a ferromagnetic core extending through the secondary inductor and into the earphone unit for selectively coupling with the primary inductor.
• the power providing system comprises at least one inductive coil, the inductive coil being selectively connectable to: at least one charging circuit for connecting the inductive coil to a power pack via a rectifier for charging the power pack when the secondary inductor is inductively coupled to the primary inductor; and at least one driving circuit connectable to the power pack for providing a varying electrical potential to the inductive coil such that the inductive coil transfers power to an external inductor wired to an external electrical load.
• the power pack is selected from the group comprising: nickel-cadmium cells, nickel metal hydride cells, alkaline cells, flow batteries, rechargeable electrochemical cells and capacitors.
• the power providing system comprising a ferromagnetic core for guiding magnetic flux through the inductive coil when inductively coupled.
• the driver comprises at least one switching unit for intermittently connecting the power pack to the inductive coil at high frequency.
• the power providing system additionally comprises a jack for conductively connecting the power pack to an external power source for charging purposes.
• the power providing system may additionally comprise a jack for conductively connecting the power pack to the external electrical load.
• the power pack is configured to power the computer.
• an inductive charger comprising at least one inductive coil and at least one chargeable power pack, the charger additionally comprising: at least one charging circuit for connecting the inductive coil to the power pack when the inductive coil is inductively coupled to a primary coil wired to a power supply for charging the power pack; and at least one driving circuit connectable to the power pack for providing a varying electrical potential to the inductive coil such that the inductive coil is inductively coupleable to a secondary coil wired to an electrical load.
• Fig. 1 is a schematic illustration of an inductive power providing means for powering a computer, in accordance with one embodiment of the present invention
• Fig. 2 is a schematic illustration of a computer provided with a secondary inductive coil incorporated within the base thereof, for inductively powering the computer by bringing into proximity with a power supplying inductive coil, according to another embodiment of the invention;
• Fig. 3 shows the jack sockets of a portable computer according to a further embodiment of the invention for coupling to an electricity mains power source via an inductive couple or via a conventional power supply
• Fig. 4 is a schematic illustration of a computer carrying case according to another embodiment of the invention with an inductive power coil built into the base thereof;
• Fig. 5 is a schematic illustration of another embodiment of the computer carrying case having an inductive power coil built into the handle thereof;
• Fig. 6 is a schematic illustration of still another embodiment of the computer carrying case having an inductive power coil built into the shoulder strap thereof;
• Figs. 7a and 7b are schematic illustrations of a retrofittable carrying handle for a portable computer with a built-in inductive power coil according to further embodiments of the invention
• Fig. 8 is a schematic illustration of a fashion-tag attachment with a built-in inductive power coil in accordance with still another embodiment of the invention
• Figs. 9a and 9b are schematic illustrations of a computer provided with another embodiment of the invention including a retractable secondary inductive coil attachment;
• Fig. 10 is a schematic illustration of an inductive charger for a mobile communication device of a further embodiment of the invention.
• Figs. 11a and 1 Ib are schematic illustrations of a mobile communication device with an inductive charger built into the skin thereof according to another embodiment of the invention.
• Fig. 12a is a schematic illustration of a self-adhesive inductive charger for a mobile communication device adhered to a power cell according to another embodiment of the invention.
• Fig. 12b is a schematic illustration of how the self-adhesive inductive charger of Fig. 12a may be used to charge cells;
• Fig. 13 is a schematic illustration of an inductive charger of another embodiment of the invention having a hermaphrodite power connector
• Figs. 14a-c are schematic illustrations of a protective case according to a further embodiment of the invention with a built-in an inductive charger for a mobile communication device
• Fig. 15 is a schematic illustration of a mobile communication device with an inductive charger built into a fashion tag
• Fig. 16 is a schematic illustration of an inductive charger for a mobile communication device with a combined data connector
• Fig. 17 is a block diagram showing the main elements of a charger for an audio device incorporated into an earphone unit in accordance with another embodiment of the invention
• Fig. 18a is a schematic diagram of a charger for an audio device according to another embodiment of the invention, wherein the voice coil of a speaker is wired to the power cell of the audio device and is inductively coupleable to a primary inductor;
• Fig. 18b is a block diagram showing the main elements of a switching unit for connecting the charger of Fig. 18a to an audio device;
• Fig. 19a is a schematic diagram of another embodiment of the charger for an audio device wherein an induction loop is incorporated into a neck support of the earphone unit;
• Fig. 19b is a schematic diagram of still another embodiment of the charger for an audio device wherein an induction loop is formed by connecting contact-terminals incorporated into the earphone cables;
• Fig. 19c is a schematic representation of an embodiment of the charger for an audio device wherein an inductive core extends through an internal secondary coil and into the earphone unit for coupling with an external primary inductor;
• Fig. 20 is a flowchart showing a possible method for charging the internal power cell of an audio device
• Figs. 21a and 21b are block diagrams schematically representing an inductive charger according a further embodiment of the invention in charging and driving modes respectively;
• Fig. 22a is a schematic representation of another embodiment of the inductive charger being charged by a primary coil
• Fig. 22b is a schematic representation of the inductive charger of Fig. 22a being used to charge a mobile telephone wired to a secondary coil;
• Fig. 23a is a schematic representation of a mobile computer being powered by a primary coil via an integral inductive coil according to another embodiment of the invention
• Fig. 23b is a schematic representation of a mobile telephone being charged by the inductive coil of Fig. 23a.
• a power providing means 10 for a portable computer 12 consisting of a secondary inductor 14 wired to the portable computer by a connecting wire 15 that is typically a two stripe multi-fiber insulated wire, such as used for providing power to portable computers via a transformer.
• the secondary inductor 14 is essentially a coil which can be brought into proximity with a primary inductor 16 which is essentially another coil hardwired to a mains power supply 18.
• the primary coil 16 and secondary coil 14 thus form an inductive power couple 20, allowing power to be provided to the portable computer 12.
• the primary coil 16 may be situated in the table top 18 of a conference table, for example. By supplying power inductively in this manner, trailing wires may be avoided, providing a neater, safer and more flexible work environment.
• the power providing means 10 may also be applicable to the provision of power to other electrical devices such as a desktop computer, handheld computer, vehicle mounted computer or the like. Power providing means 10 may also be used by other portable systems such as hand-held DVD players, projectors, hand-held televisions, digital picture frames or sound systems for example.
• the secondary coil 14 may be integral to the portable computer 12, being built into the base thereof, under the keyboard. Positioning the computer 12 over a primary coil 16a in a work-surface 22, for example, enables power to be provided thereto, without trailing wires. The power may be used to recharge the electrochemical power pack (battery) 24 or to power the portable computer 12.
• the secondary coil 14a may be coupled to a portable computer 12 designed for optional power provision in this manner, via a jack 26 that is plugged into a dedicated jack socket 28 designed for coupling the secondary coil 14a.
• the dedicated jack socket 28 is separate from the power supply jack socket 30 supplied for coupling to a power supply (not shown) of the type consisting of a transformer for plugging into a power mains socket that is typically provided.
• the dedicated jack plug 26 and jack socket 28 may usefully be physically different from power supply jack socket 30 and jack plug (not shown), to prevent misconnection.
• the inductive and transformer sockets 28, 30 are preferably appropriately labeled, perhaps with letters I and T for inductive and transformer, to prevent confusion.
• the secondary coil 14a is connected to the portable computer 12 via the power jack socket 30 designed for coupling to a mains via a power supply of the transformer type.
• existing portable computers may be retrofitted with a secondary coil 14a for inductive powering.
• Power may alternatively be provided to the portable computer 12 via connecting points designed for coupling to a rechargeable electrochemical power pack within the housing for the power pack.
• the secondary coil 14a may be provided as a sort of puck on a wire that can be positioned over an access point in a surface where a primary coil 16 is provided.
• the secondary coil 14b is preferably incorporated into an accessory that has additional functionality.
• it may be built into the side of a carrying case 40 or skin provided for carrying the portable computer 12.
• the secondary coil 14c is built into the handle 42 of a carrying case 44.
• the secondary coil 14d is built into the shoulder strap 46 of a carrying case 48 which being flexible, gives more flexibility to the user, in that the computer 12 can be left in its case, and situated anywhere within a radius of about 80 cm from a "power-spot" where a primary coil 16 is situated.
• a retrofittable carrying handle 52 for a computer 12 is shown.
• the handle 52 is attached to the computer by straps 54 and incorporates a built-in inductive power coil 14e electrically coupled to the computer via a power plug 56 which plugs into the power jack 30 of the computer 12.
• the straps 54 Whilst the computer 12 is being carried, the straps 54 surround and support the computer 12 as shown in Fig. 7b. However, as shown in Fig. 7a, when the computer 12 is laid down and in use, the support straps 54 are opened allowing the inductive power coil 14e to be coupled to a primary coil 16 situated anywhere within their radius.
• the inductive power coil 14 may be concealed inside a fashion-tag 62 attached to the computer 12 for example by a connecting chain 64 or the like.
• the computer may draw power from a primary coil 16.
• a retractable secondary inductive coil attachment 70 may be retrofitted to a portable computer 12, as shown in Figs. 9a and 9b.
• the secondary inductive coil 14f is held in a tongue 74 mounted upon the base of the computer 12 and when the computer 12 is in use as shown in Fig. 9a, the tongue 74 may be extended so that the secondary coil 14f may couple with a power spot 16 within its radius.
• the thickness of the secondary inductive coil attachment 70 is less than the height of the feet 13 of the computer 12 so that the attachment 70 does not prevent the computer 12 lying flat along a table top.
• an inductive charger 100 is shown for charging the power cells of a mobile communication device 200 such as mobile telephone, personal digital assistant (PDA), camera or the like, indeed many mobile devices include all of these functions.
• the charger 100 consists of a secondary coil 120 wired to the mobile communication device 200 typically via a power jack socket 220 of by a connecting wire 140 - typically a two stripe multi-fiber insulating wire, such as used for electrically connecting a power source to a mobile communication device via a transformer.
• the secondary coil 120 can be brought into proximity with a primary coil 10 hardwired to a mains power supply, to form an inductive power couple, allowing power to be provided to recharge the cells 240 (Figs. 12a and 12b) of the mobile communication device 200.
• the primary coil 10 may be situated in the table top 20 of a conference table, for example, thereby allowing a phone 200 to be recharged thereby. By inductively recharging in this manner, trailing wires may be avoided or at least minimized.
• the secondary coil 120 may be provided for example as a sort of puck 122 on a wire that can be positioned over an access point in a surface where a primary coil 10 is provided. Alternatively the secondary coil 120 may be built into an accessory of the telephone 200.
• the secondary coil 120 may be built into the skin or casing 260a, 260b of the mobile communication device. Positioning the mobile communication device over a primary coil 10, as shown in Fig. 1 Ib, at an access point in a work-surface 20, for example, enables power to be provided to the charger thereby charging the power cells 240 of the mobile communication device 200 without trailing wires.
• the charger may be connected directly to the terminals of the power cells. Alternatively the charger may be connected to the power cells via the power jack socket 220 of the mobile communication device 200.
• the secondary coil 120 may be provided with an adhesive surface 122 so that the coil 120 may be adhered directly onto the power cells 240 of a mobile telecommunication device 200 in conductive contact with the terminals of the power cells.
• the cells 240 may be recharged.
• the cells 240 are recharged directly from the secondary coil 120 so the cells 240 do not need to be connected to the device in order for them to be charged.
• the secondary coil 120 is wired to a hermaphrodite power connector 160 including both a male plug 162 and a female socket 164.
• the male plug 162 of the hermaphrodite power connector 160 may be coupled to the power jack socket 220 of the device while still providing a female socket 164 for accommodating the plug 40 of a conventional conductive charger.
• a user may select between charging the power cells 240 of the mobile communication device 200 using the inductive charger 100 or the conductive type charger.
• the selection may be facilitated by means of a switch although, preferably, the power connector 160 is configured automatically to select the inductive charger whenever the secondary coil 120 is inductively coupled to a primary coil 10 and to select the conductive power supply whenever the female socket 164 is conductively coupled to a power source.
• the secondary coil 120 may be built into a protective or fashionable case 300 which may be fitted to a mobile communication device 200.
• the secondary coil 120 is typically wired to a hermaphrodite power connector 160 within the case 300 which is configured to couple with the power jack socket 220 of the mobile communication device.
• FIG. 15 A further embodiment is illustrated in Fig. 15 showing a mobile communication device 200 having a secondary coil concealed within a fashionable tag 400, such as a so called “mobile dangler” or the like, which may be plugged directly into the power jack socket 220 with additional mechanical support 420 optionally provided when necessary.
• the inductive charger 100 of the invention may thus be incorporated within a fashion accessory for the mobile communication device.
• the secondary coil 120 may be concealed in other accessories of the mobile telecommunication device such as a belt clip, neck cord, hand strap or the like.
• an inductive charger 700 has a data channel coupled to the data jack socket 280 of the mobile communication device 200.
• a USB (Universal Serial Bus) cable 720 leading to a USB plug is wired to the inductive charger which may be connected to USB jack socket 820 of a computer 800, for example, thereby providing a data link between the mobile communication device 200 and the computer 800.
• USB Universal Serial Bus
• the USB connector 740 may, in addition, draw power from the computer 800 and may thus be used to provide power to charge the power cells 120 of the mobile communication device 200 directly.
• the charger 700 may be configured to select automatically between charging the power cells 120 from the USB connector 740 or the secondary coil 120 depending upon the availability of power.
• United States Patent No. 7,180,265 to Nokia Corporation, titled "Charging Device with an Induction Coil” describes an inductive charging device for charging portable electronic devices with small footprints.
• the charger described in '265 includes a battery; a first induction coil coupled to the battery; and an induction core extending through the first induction coil.
• the induction core has a portion which extends in an outward direction from the charging device and is adapted to removably couple with a second induction coil of a portable electronic device by extending into the second induction coil.
• the charger described in '265 is essentially a charging hook upon which electronic devices may be suspended by support loops.
• the hook is coupled to the first inductive coil and is adapted to charge up the electronic devices via the secondary inductive coils which may be incorporated into the support loops.
• the support strap itself is undesirable, and as discussed hereinabove, there is a general desire to limit the number of wires, straps and cables.
• FIG. 17 a block diagram showing the main elements of an inductive charger 1100 for charging the internal power cells 1220 of an audio device 1200, according to an embodiment of the invention.
• the charger 1100 includes a secondary inductor 1140 wired to the power cells 1220 of the audio device 1200 via a rectifier 1240.
• An inductive element 1180 is incorporated into the earphone unit 1120 for inductively coupling the secondary inductor 1140 to an external primary inductor 1320.
• the primary inductor 1320 is typically wired to a power supply 1300 via a driving unit 1310.
• the driving unit 1310 provides the electronics necessary to drive the primary inductor 1320, such as a switching unit providing a high frequency oscillating voltage supply, for example.
• Charger 1100 is suitable for use with audio devices 1200 requiring earphones 1121 connected via earphone cables 1122 such as, telephones, media players, personal digital assistants (PDA), Walkman®s, portable CD players, portable DVD players, mobile communications devices and the like.
• earphones 1121 connected via earphone cables 1122
• PDA personal digital assistants
• Walkman®s portable CD players
• portable DVD players portable DVD players
• mobile communications devices and the like.
• the inductive charger 1100 is incorporated in the earphone unit 1120 of the audio device 1200.
• the inductive charger 1100 of the present invention is incorporated into the earphone unit 1120, the dimensions of the audio device 1200 itself are not compromised by the addition of peripheral elements such as the support strap described in United States Patent No. 7, 180,265 to Nokia Corporation, for example.
• the earphone unit 2120 includes a moving coil speaker 2122 incorporated within an earpiece 2124 which is connected via a signal line 2125 to a plug 2126 for coupling to the audio device 2200 via an earphone jack 2202.
• the voice coil 2140 of the moving coil speaker 2122 is a transducer that receives electrical signals from the signal lines 2125 and converts them to audio signals.
• the voice coil 2140 is additionally configured to be couplable to an external primary inductor 2320 which may be housed within a docking station 2322.
• the voice coil 2140 may serve as the secondary inductor 1140 (Fig. 17) of the inductive charger 2100, providing power to the audio device via the signal lines 2125.
• dedicated power lines within the earphone unit 2120 may provide a conductive connection between the voice coil 2140 and the internal power cell 220 of the audio device 200 via a rectifier 1240 (Fig. 17).
• Fig. 18b is a block diagram of the main elements of a switching unit 2270 for connecting the charger 2100 of Fig. 18a to an audio device 2200.
• the switching unit 2270 is provided to selectively connect the voice coil 2140 to the audio device 2200.
• the switching unit 2270 may be a separate unit that is retrofittable both to the audio device 2200 and to the earphone unit 2120. Alternatively, the switching unit 2270 may be incorporated into either the audio device 2200 or the ear
• the switching unit 2270 may connect the voice coil terminal C to either an audio signal input A or to a charger output B of a switching circuit 2272.
• the audio signal input A receives an audio signal 2250 from an amplifier 2260 which is communicated to the voice coil 2140.
• the charger output B is connected to the power cell 2220 via a rectifier 2240 and may be used for charging the power cell 2220 when the voice coil 2140 is coupled to primary inductor 2320.
• the switching circuit 2272 may be controlled by a frequency detector 2274 which is configured and operable to detect high frequency voltage fluctuations along the signal line. High frequency voltage fluctuations are indicative that the voice coil 2140 is coupled to an active primary inductor 2320. Therefore, when such high frequency fluctuations are detected, the switching circuit 2272 may be connected to the charger output B for charging the power cell 2220.
• a frequency detector 2274 which is configured and operable to detect high frequency voltage fluctuations along the signal line. High frequency voltage fluctuations are indicative that the voice coil 2140 is coupled to an active primary inductor 2320. Therefore, when such high frequency fluctuations are detected, the switching circuit 2272 may be connected to the charger output B for charging the power cell 2220.
• Figs. 19a-c are schematic diagrams showing various embodiments of charger 3100, 4100, 5100 for an audio device 3200, 4200, 5200.
• the earphone unit 3120 includes a neck support 3122.
• an induction loop 3140 of conductive wire 3142 that is wound into a coil and connected to the internal power cell 1220 (Fig. 17) of the audio device 3200 via a rectifier 1240 (Fig. 17).
• the inductive loop 3140 is configured to inductively couple with an external primary inductor 320.
• the audio device 3200 may be conveniently stored by suspending the neck support 3122 from a hook 3322.
• the hook 3322 is fabricated from a ferromagnetic material which extends through a primary coil 3320.
• the ferromagnetic material forms a common inductive core 3180 between the primary coil 3320 and the inductive loop 3140 within the neck support 3122.
• the primary coil 3320 and inductive loop 3140 thus form an inductive couple such that power may be inductively transferred from the primary coil 3320 to the inductive loop 3140, thereby charging the power cells 1220 (Fig. 17) of the audio device 3200.
• the inductive couple may be improved by the inclusion of a ferromagnetic element (not shown) and may be incorporated into the neck support 3122 and configured so as to couple with the ferromagnetic inductive core 3180 of the hook 3322 so as to complete a magnetic circuit.
• a ferromagnetic element (not shown) and may be incorporated into the neck support 3122 and configured so as to couple with the ferromagnetic inductive core 3180 of the hook 3322 so as to complete a magnetic circuit.
• a secondary inductor may be housed in various other components of an earphone unit.
• a secondary induction coil may be housed in a dedicated unit within the earphone cable.
• a secondary coil may be incorporated into a microphone housing such as is commonly included in the earphone cable of a cellular telephone.
• a secondary coil may be incorporated into a cable stowage unit such as a spring loaded winder as is sometimes included with earphone units for convenient storage.
• FIG. 19b An alternative embodiment of the induction loop is schematically represented in Fig. 19b, wherein a charger 4100 for an audio device 4200 according to another embodiment of the current invention is shown.
• the earphone unit 4120 of this embodiment includes two earpieces 4122a, 4122b, each connected to the audio device 4200 via its own earphone cable 4124a, 4124b.
• a bundle of induction wires 4140, embedded in the earphone cables 4124, is connected to the internal power cell 1220 (Fig. 17) of the audio device 4200 via the rectifier 1240 (Fig. 17).
• Contact-terminals 4142a and 4142b at each end of the bundle of induction wires 4140 are configured to conductively couple the ends of the bundle of induction wires 4140 thereby forming an induction loop.
• the induction loop may be coupled with an external primary coil (not shown) such that power may be inductively transferred from the primary coil to the inductive loop.
• Fig. 19c is a schematic representation of a charger 5100 for an audio device 5200 according to still another embodiment of the invention.
• the audio device 5200 incorporates an internal secondary coil 5140 connected to the internal power cell 5220 via the rectifier 5240.
• An inductive core 5180 extends through the internal secondary coil 5140 and into the earphone unit 5120 for coupling with a primary inductor 5320.
• the primary inductor may, for example, be incorporated into a hook (not shown) for suspending the audio device 5200.
• Fig. 20 is a flowchart showing a method for inductively charging the internal power cell of an audio device in accordance with one embodiment of the invention.
• the method comprises the steps of: step (a) providing an inductive charger incorporated within the earphone unit of the audio device, including a secondary inductor connected to the power cell via a rectifier; step (b) providing an external primary inductor connected to a power source via a driver; step (c) inductively coupling the secondary inductor of the charger to the external primary inductor, and step (d) providing a variable voltage to the primary inductor.
• Figs. 21a and 21b are block diagrams schematically representing the inductive charger 6100 for use with another embodiment of the invention.
• the inductive charger 6100 consists of an inductive coil 6120 and a chargeable power pack 6140 which can be connected to each other via a charging circuit 6160 or alternatively via a driving circuit 6180. It is a particular feature of the current invention that the inductive charger 6100 may be switched between two modes: (a) a charging mode as shown in Fig. 21a, and (b) a driving mode, as shown in Fig. 21b.
• a mode selector 6170 is used to select between the two modes.
• the inductive coil 6120 is coupled to an external primary inductive coil 6220 which is connected to a power supply 6240 preferably via a driving unit 6260.
• the mode selector 6170 is configured to connect the inductive coil 6120 to the power pack 6140 via the charging circuit 6160.
• the external primary coil 6220 In the charging mode, the external primary coil 6220 generates an oscillating magnetic field.
• the internal inductive coil 6120 is placed in the vicinity of the external primary coil
• Fig. 21b representing the inductive charger 6100 in driving mode, where the inductive coil 6120 is inductively coupled to an external secondary inductive coil 6320 which is wired to an electric load 6340.
• the mode selector 6170 is configured to connect the inductive coil 6120 to the power pack 6140 via the driving circuit 6180.
• the power supply 6140 provides power to the driver circuit 6180 which provides a varying electrical potential to drive the inductive coil 6120.
• the driver circuit 6180 typically includes a high frequency switching unit intermittently connecting the power pack 6140 to the inductive coil 6120.
• the varying electrical potential across the inductive coil 6120 produces an oscillating magnetic field. Therefore, an external secondary coil 6320 which is brought into the vicinity of the inductive charger 6100 may inductively couple with the inductive coil 6120.
• An electric load 6340 wired to the secondary coil 6320 may thereby draw power from the power pack 6140.
• rechargeable power packs are known and may be suitable for use with various embodiments of the inductive charger 6100.
• rechargeable electrochemical cells include nickel-cadmium cells, nickel metal hydride cells, alkaline cells, flow batteries and the like.
• Other power storage devices such as lead alkali accumulators, capacitors and supercapacitors may also be charged by the inductive charger 6100.
• a housing 7110 contains an inductive coil 7120 which is wrapped around a ferromagnetic core 7122 and is connected to an internal power pack 7140 via a control box 7130.
• the control box 7130 contains driving circuitry for the driving mode, charging circuitry for the charging mode and a mode selector (not shown).
• additional circuitry may be provided for charging the power pack 7140 from the mains or other external power source, such as solar power or the like, via a dedicated jack.
• a dedicated jack may also be provided for conductively connecting with and the powering of an external electrical load.
• Fig. 22a shows the inductive charger 7100 being charged up by an inductive power outlet 7200 which consists of a primary coil 7220 concealed behind a facing layer, such as Formica or wood veneer, of a platform 7280 such as a desk-top, a kitchen work-top, a conference table or a work bench for example.
• the primary coil 7220 is wired to a power supply 7240 via a driving unit 7260 providing the electronics necessary to drive the primary coil 7120.
• Driving electronics may include a switching unit providing a high frequency oscillating voltage supply, for example.
• inductive power outlets 7200 As inductive power outlets 7200 become more widespread, it is considered likely that devices may be hardwired to secondary coils, to draw their power inductively therefrom.
• mobile phones, media players and the like which are generally connected to external chargers via connecting wires may be provided with internal charging circuitry that includes a secondary coil for inductively coupling to inductive power outlet 7200.
• Fig. 22b shows a mobile phone 7300 which has an integral secondary inductive coil
• the mobile phone 7320 connected to its internal power source 7340 via a rectifier (not shown).
• inductive power outlet 7200 such as shown in Fig.
• the mobile phone may be charged by placing it on top of the inductive charger 7100, as shown in Fig. 7b.
• the inductive charger 7100 With the inductive charger 7100 set to driving mode, the mobile phones secondary coil 7320 inductively couples with the internal inductive coil 7120 of the inductive charger 7100 and draws power therefrom.
• the inductive charger 8100 is incorporated into a mobile computer 8000.
• the mobile computer 8000 has a built-in inductive coil 8120 for powering the computer from an inductive power outlet 8200, as shown in Fig. 23 a.
• the inductive coil 8120 may power the computer and / or charge the internal power pack 8140 of the mobile computer.
• the inductive coil 8120 of the computer 8000 may additionally be used to charge an external device such as a mobile phone 8300 with an in-built secondary coil 8320, as shown in Fig. 8b.
• An external device such as a mobile phone 8300 with an in-built secondary coil 8320, as shown in Fig. 8b.
• a similar use is already made of computers 8000 to charge external devices such as media players, mobile phones, mice, Bluetooth devices and the like, generally using dedicated cables and via standard ports, such as their USB (universal serial bus) ports.
• USB universal serial bus
• inductive chargers may be incorporated into other hosts, such as electric cars, generators, emergency lights or the like for charging electrical devices thereby.

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