Contactless power supply

A contactless power supply and system is provided that comprises an inductive coil disposed within a seatback tray of a mobile platform, e.g. a commercial aircraft, and a receptor disposed within a computing device, wherein the computing device is placed on the seatback tray and the inductive coil is energized, thereby providing electrical current to power the computing device. The contactless power supply further comprises a shielding member that is installed in the computing device to protect components of the personal computer from any detrimental effects of magnetic fields produced by the inductive coil.

FIELD OF THE INVENTION

The present invention relates generally to power supplies and more particularly to contactless, or wireless, power supplies.

BACKGROUND OF THE INVENTION

Wireless communications are continuously being developed for numerous applications in the field of computing. For example, laptop computers are capable of communicating with remote servers through radio frequency (RF) transmission to access services such as the Internet or e-mail. Additionally, personal digital assistants (PDAs) are similarly capable of accessing remote services through RF transmission. Accordingly, physical wires or cords are not required with wireless communications, which results in significant advantages in terms of portability and minimal equipment required for continuous computing operations.

Although wireless applications in the field of computing are continually expanding, a wireless solution to the traditional power supply or brick has not yet been developed. If a user is operating a laptop computer wirelessly from a remote location that does not have an adaptable power supply, i.e. 110V AC power outlet, the operating time of the laptop computer is limited to the available charge provided by at least one rechargeable battery, which is typically provided within the laptop computer. As a result, the amount of time that the laptop computer remains operational is limited by the life of the rechargeable battery when access to power via a power cord or brick is unavailable.

One device that provides wireless power transfer is disclosed in U.S. Pat. No. 6,278,210 to Fatula, Jr. et al., wherein power is supplied to a rotary element by magnetic induction. Generally, a magnetic flux is introduced in an induction assembly, which causes an alternating current that is converted to a direct current, which is further stored in an electrical storage device without the use of wires. Unfortunately, the device of Fatula requires moving parts and is relatively large for use in portable devices such as laptop computers.

Accordingly, there remains a need in the art for a contactless power supply for use with computing devices such as laptop computers and PDAs. A need further exists for a contactless power supply that also provides battery charging capability for computing devices, furthermore onboard a mobile platform, e.g. a commercial airline, such that operating time of the computing device is not limited to the available charge of rechargeable batteries.

SUMMARY OF THE INVENTION

In one preferred form, the present invention provides a contactless power supply for use with a computing device disposed proximate a charging unit that comprises an inductive coil disposed within the charging unit and a receptor disposed within the computing device. Accordingly, the inductive coil provides electrical current, through its generation of a magnetic field, to the receptor to power the computing device and to further charge any rechargeable batteries of the computing device.

Preferably, the contactless power supply is employed on a mobile platform, e.g. a commercial aircraft, wherein the inductive coil is disposed in a seatback tray and a user simply places a computing device such as a laptop computer on the seatback tray in order to provide power for continuous operation. Additionally, the power supply may further provide battery charging capability to the computing device.

The contactless power supply may further comprise a shielding member disposed within the computing device in order to protect elements of the computing device from any detrimental effects of magnetic fields produced by the inductive coil. For example, the hard drive and any disk drives are preferably shielded to prevent contents therein from being inadvertently erased by the magnetic fields. Additional components of the computing device such as the internal clock, among others, may also be shielded as required, depending on the strength of the inductive coil.

The computing device according to the present invention may be a personal computer, a laptop computer, or a personal digital assistant (PDA), among others. Accordingly, an airline passenger or crewmember simply places the computing device on the seatback tray in order to have continuous power throughout the duration of the flight.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings, a contactless power supply according to the present invention is illustrated and generally indicated by reference numeral 10 in FIG. 1 . The contactless power supply comprises an inductive coil 12 disposed within a charging unit 14 , along with a receptor 16 disposed within or on a computing device 18 , wherein the computing device 18 is positioned proximate the charging unit 14 as shown. When energized, the inductive coil 12 generates magnetic fields to provide electrical current to the receptor 16 , which powers the computing device 18 . Further, the electrical current may also be used to charge batteries (not shown) of the computing device 18 in addition to supplying power. Accordingly, the computing device 18 is powered without the use of conventional wires, power cords, or power supply bricks.

More specifically, the contactless power supply 10 comprises a two-part transformer, wherein the transformer has a flat configuration so as to fit within, for example, a seatback tray or a desktop. The first part of the transformer is located within the seatback tray and is coupled to a source of AC power. The second part of the transformer, hereinafter referred to as receiving coil and core, is located within the computing device 18 and is coupled to a rectifier that converts AC power to DC power. When magnetic field lines are approximately 90 degrees to the first part of the transformer when the receiving coil and core are placed within the field, current is induced into the computing device 18 . Further, a pair of diodes in the receiving coil and core produce direct current for the computing device 18 .

Preferably, the receptor 16 is a thin flat coil disposed on or within the computing device 18 , which is further sized and positioned according to power requirements of specific applications. In one form, the receptor 16 is disposed on a bottom surface of the computing device 18 . Additionally, the inductive coil 12 is similarly positioned within the charging unit 14 and sized according to specific power requirements. Furthermore, the computing device 18 may be a personal computer, a laptop computer, or a personal digital assistant (PDA), among other computing devices commonly known in the art.

Referring to FIGS. 2 and 3 , the preferred embodiment of the present invention provides the contactless power supply 10 for use onboard a mobile platform, e.g. a commercial aircraft. Accordingly, the inductive coil 12 is disposed within a seatback tray 20 , and a passenger simply places the computing device 18 , illustrated herein as a laptop computer, on the seatback tray 20 to power the computing device 18 as previously set forth. As a result, the computing device 18 may be operated throughout the duration of the flight and is not limited by the available charge of the batteries disposed therein. Further, the contactless power supply 10 may also be configured to recharge batteries of the computing device 10 while simultaneously providing power.

Although the detailed description herein is directed to a contactless power supply wherein the mobile platform is an aircraft, the invention is also applicable to other modes of mass transit such as ship, train, bus, and others. Accordingly, the reference to aircraft should not be construed as limiting the scope of the present invention.

In another form, the contactless power supply 10 further comprises a shielding member (not shown) that protects elements of the computing device 18 from detrimental effects of magnetic fields produced by the inductive coil 12 . More specifically, the hard drive and any disk drives within the computing device 18 are preferably shielded to prevent contents therein from being inadvertently erased by the magnetic fields. Additional components of the computing device 18 such as the internal clock, among others, may also be shielded as required, depending on the strength of the inductive coil 12 .

In yet another form, the present invention provides a method of wirelessly providing power to the computing device 18 onboard a mobile platform, wherein a computing device 18 is placed on the seatback tray 20 and the inductive coil 12 is energized in order to provide electrical current to the receptor 16 disposed within or on the computing device 18 . Once the inductive coil 12 is energized, power is provided to the computing device 18 for the duration of the flight.

Preferably, a switch (not shown) is installed on the seatback tray 20 so that a user can energize the contactless power supply 10 as required. Further, the contactless power supply 10 also comprises a disabling switch (not shown), which may be a mechanical switch or other switching methods commonly known in the art such as optical, that turns off the contactless power supply 10 when the seatback tray 20 is returned to its stowed position. Moreover, the seatback tray 20 is in communication with aircraft systems such that the contactless power supply 10 may be disabled under specific circumstances such as takeoff, landing, or emergency situations.

Accordingly, a contactless power supply is provided that eliminates the use of traditional hard wires, cables, or power supply bricks that are typically used with computing devices such as personal computers and laptop computers. As a result, a user is capable of extending the operating time of a computing device, further without the need for additional equipment and physical wiring.