1. Field of the Invention
The present invention relates to electronic systems and methods for providing electrical power and/or data to one or more electronic or electrically powered devices with a power delivery surface.
2. State of the Prior Art
A variety of electronic or electrically powered devices, such as toys, game devices, cell phones, laptop computers, cameras, and personal digital assistants, have been developed along with ways for powering them. Mobile electronic devices typically include and are powered by batteries which are rechargeable by connecting them through power cord units, which include transformers and/or power converters, to a power source, such as an electric wall outlet or power grid, an automobile or other vehicle accessory electric outlet plug receptacle or the like, either during use of the electronic device or between uses. A non-mobile electronic device is generally one that is powered through a power cord unit and is not intended to be moved during use any farther than the reach of the power cord, so it generally does not have or need batteries for powering the device between plug-ins.
In a typical set-up for a mobile device, the power cord unit includes an outlet connector or plug for connecting it to the power source and a battery connector for connecting it to a corresponding battery power receptacle of the battery. The outlet connector or plug and battery connectors are in communication with each other so electrical signals flow between them. In this way, the power source charges the battery through the power cord unit.
In some setups, the power cord unit may include a power adapter, transformer, or converter connected to the outlet and battery connectors through AC input and DC output cords, respectively. The power adapter adapts an AC input voltage received from the power source through the outlet connector and AC input cord to output a DC voltage through the DC output cord. Others include adapters, transformers, or converters connected to the outlet and battery connectors through DC input and DC output cords. The DC output current flows through the receptacle and is used to charge the battery.
Manufacturers, however, generally make their own models of electronic devices and do not make their power cord unit compatible with the electronic devices of other manufacturers, or with other types of electronic devices. As a result, a battery connector made by one manufacturer will typically not fit into the battery power receptacle made by another manufacturer. Further, a battery connector made for one type of device typically will not fit into the battery power receptacle made for another type of device. Manufacturers make these connectors unique to their own devices for several reasons, such as cost, liability concerns, different power requirements, and to acquire or hold a market share.
However, the proliferation of unique power cords that are not compatible with other devices can be troublesome for consumers because they have to buy unique power cord units for their particular electronic devices and deal with the plethora of different power cords required for their devices. Since people tend to switch devices often, it is inconvenient, expensive, and wasteful for them to also have to switch power cord units, too. Unfortunately, power cord units that are no longer useful are often discarded, which is also wasteful and harmful to the environment. Also, people generally own a number of different types of electronic devices and owning a power cord unit for each one is inconvenient because the consumer must deal with a large quantity of power cord units and the confusion and tangle of power cords the situation creates.
The accompanying drawings, which are incorporated in and form a part of the specification, illustrate example implementations of the present invention, but not the only ways the invention can be implemented, and together with the written description and claims, serve to explain the principles of the invention.
In the drawings:
a is a block diagram of example inductive transmitting and receiving circuits with a feedback loop;
a and 16b are isometric views of the outside and inside, respectively, of a gel case or shell for mounting the power receiver module on a power receiving device;
An example charging pad 10 and enabled power receiving device 20 are shown in
The top surface 11 of charging pad 10 comprises an array 12 of contact strips 14, 16, which are energized with low voltage DC or AC so that every other strip, e.g., the strips 14, are positive and the strips 16 in-between the positive strips 14 are negative, or vice versa, as illustrated in
On the underside 22 of one example enabled device 20, there are a plurality of conduction contact points 26 arranged in a “constellation” configuration or pattern 24 as shown in
The contact constellation 24 on the enabled device 20 and the contact strip array 12 on the charging pad 10 form a geometrically complementary pair with the property that electrical power can be transferred from the pad 10 into the device 20 regardless of the position and orientation of each particular device 20 on the pad. Several orientations are shown for example in
As illustrated in
In this architecture, the voltage on the power delivery surface 11 of the charging pad 10 is fixed and independent of the devices 20 resting on the pad surface 11. Each individual device 20 that gets positioned on the charging pad 10 is responsible for conditioning the electric power obtained from the charging pad 10 to power that is appropriate for its own use. This scheme inherently allows for multiple devices 20 of various manufacturers with various power requirements to be charged from the same charging pad 10.
A function block diagram of the overall system is shown in
A control and safety system 29 associated with, and preferably a part of, the charging pad 10 renders the contact array 12 of the power delivery surface 11 benign and safe to the user. The control and safety system 29 is not part of this invention, thus is not described in detail. Suffice it to say that the control and safety system 29 energizes the array 12 only when a compliant load is detected. The system 29 senses the presence of non-enabled devices such as keys or hands and instantly safely shuts down.
Inductive power transfer uses a pad 10′ that transfers power wirelessly to one or more devices 20′ resting on it. This is achieved through electromagnetic induction. An example inductive power pad 10′ and complementary inductive receiver device 20′ are shown in
Within the pad 10 is located an array 18 of coils 38 as shown in
Various means can be implemented to control the pad 10 in order to minimize stray radiation and losses. In some cases, the number of coils 38 in the array 18 (as shown in
In other implementations, control and sense circuitry can independently drive one or more of the coils 38 on the pad 10′ with an AC power waveform to create an alternating magnetic field. Example drive circuitry will be discussed in more detail below.
An inductive receiver device 20′ is shown in
To improve transfer efficiency, the inductive receiver pickup circuit 24′ can include a resonating inductive circuit 36, as illustrated in
Efficiency is improved on the transmitter circuit side 34 by allowing a circulating current to flow through the resonating capacitor C2 in parallel to the AC generator 44 and coil 38. If not for this capacitor C2, the current would have to flow through the AC generator 44. Note that the internal resistance of the sine wave generator is not shown explicitly in
The power driver or generator 44 supplies the AC waveform to excite the transmitter coil 38. This in turn creates an alternating magnetic field 42 at the surface 11′ of the transmitter pad 10′. It is this magnetic field 42 that induces a potential that can be extracted by the power receiver 20′.
The sense circuitry 46 serves several purposes. Firstly, the sense circuitry 46 can determine when the exciter should turn on. It may be desirable that the exciter does not turn on until a power receiver 20′ is within the appropriate distance of the pad surface 11′ to efficiently receive power. In some cases the sense circuitry 46 can determine if power is being drawn from the transmitter circuit 34. In that case, the exciter 44 can periodically turn on for a brief time while the power being drawn is measured. If no device 20′ is present on the pad 10′, then the power being drawn is presumed to be low. If a device 20′ is present on the pad 10′, the power will be measurably different than nominal, and this information can be interpreted as an indication that a compatible device 20′ is resting on the pad 10′.
As it is desirable that the transmitter 34 creates an AC excitation at the resonant frequency of the receiver circuit 36 to achieve desirable efficiency, a means of determining the receiver resonance is useful. It is worth noting that this resonant frequency changes as a function of device position with respect to the exciter coil, device load, temperature, presence of other devices, and other factors.
One means of achieving resonance is to adjust the receiver circuit 36 to be at a known, predetermined frequency. In this case the transmitter circuit 34 can be set to generate the excitation at that predetermined frequency.
Alternatively, a means can be implemented in which the exciter sense circuits hunt to find the resonance of the receiver system 36. This can be accomplished with a programmable frequency generator 35 in a feedback loop 37 with phase, amplitude, or power sensing circuits 39 that can be provided in any of a number of techniques known to persons skilled in the art, for example, as illustrated in the block diagram of
A block diagram of the overall inductive system is shown in
An embodiment of a power receiver module 50 for use on a target device 21 or 21′, either as a retro-fit or as new manufactured equipment or features is shown in
An example of an application of the power receiver module 50 embedded in a shell-type housing 52 is shown in
The power receiver module 50 can be used to provide wirefree compatibility to target devices 21 with a minimum of effort. The power receiver module makes a “black box” out of the wireless power technology within, simplifying the interface to just a few wires that get routed to the device's input power port 51 (
Typical example output ratings or specifications for low power consumption target devices 21 such as cell phones, recorder/playback devices, hearing aids, etc., may include the following (although other ratings or specifications can be used for higher power applications):
Output Voltage 5.0V (0.8V-9.0V factory adjustable)
Output Current 550 mA (100 mA-1.2 A factory adjustable)
Refer to Table 1 for power receiver module pinouts.
In other words, in an example application, the power output may be a nominal 5V on pin 1 and ground on pin 5, leaving the pins 2, 3, and 4 unused, or other values can be provided by the circuitry in the power output module 50 for different applications.
An enlarged cross-section of the example power receiver module 50 in
In the example power delivery module 50 shown in
A conductive, tapered coil spring 92 is positioned between a printed circuit board 90 and the ball bearing 80 to yieldingly push the ball bearing in to the hole 84, which helps the ball bearing 80 to maintain effective electrical contact with the contact strip 14 or 16 of the charging pad 10, even if the power delivery surface 11 is not perfectly flat. The spring 92 is electrically conductive and bears on a conductive plate 94 on the printed circuit board 90, so it conducts electric current between the ball bearing 80 and the printed circuit board 90. The plate 94 is in electrical contact with the components 96 of the printed circuit board 90, which rectify and optionally filter and condition the electric power extracted from the charging pad 10 for use by the target device 21. A top plate 98 covers and retains the printed circuit board 90 in place. Both the bottom plate 86 and top plate 98 can be rigid or semi-rigid plastic, for example, to maintain the structural integrity of the power receiver module 50. Conductive strips 100 can extend from the printed circuit board 90 to the exterior of the power receiver module 50 to form or connect to the ZIF connector pins 1, 2, 3, 4, and/or 5 shown in
As mentioned above, the power receiver module 50 is adapted to be mounted or molded in an integral manner with a shell or case 52 (see
The “gel” skin 52′ serves two purposes. First, it is an attractive, functional protective cover that provides durability to a target device 21. It also has a pleasurable feeling. It can also provide aesthetic enhancement, for example, color or pattern, to the appearance of the target mobile device 21. At the same time, the “gel” skin 52′ contains the built-in power receiver module 50, which enables the device 20 to be rechargeable wirefree.
There are many ways in which the connection between the power receiver module 50 and the input connector of the target mobile device 21 can be made. The example connector assembly 76 shown in
Other means includes but are not limited to flat flexible circuit wire (FFC), standard wires of circular cross section, wires of rectangular cross section, and many other possible means of providing an electrical connection embedded within the “gel” skin 52′. This electrical connection is required to pass electrical power from the power receiver module to a connector that mates with the input connector of the host mobile device.
In the example of
The implementation can be described in two categories: 1) the provision of an attractive, ergonomic “gel” skin 52′; and 2) the provision of the connection assembly—the connection between the power receiver module 50 and the device 21. The focus of this description will be the connection assembly 76.
The power receiver module 50 and flexible connector assembly 76 are insert-molded into the gel case or skin 52′, as depicted in
The material should also be blocked from the top and bottom surface of the power receiver module 50. Any material on either the top or bottom of the power receiver module 50 will interfere with operation and increase the overall thickness of the design. The power receiver module 50 and the thermoplastic elastomer (TPE) material that forms the gel skin 52′ will chemically bond thereby creating a durable and reliable joint. Note that other materials can be used, such as ThermoPlastic Urethane (TPU), that provide substantially the same material characteristics. The choice of specific material meeting the requirements implied by the nature of this invention can be made by one skilled in the art. This, however, does not vary significantly from the overall spirit and intent of this invention.
The electrical connection between the power receiver module 50 and the power connector 68 is established through traces 110, 112 (
Some type of strain relief mechanism is required to ensure the reliability of the connection between the flexible circuit carrier 66 and the power connector 68.
The strain relief 70 relieves the load on the connector 68 from the flexible circuit 72. The flexible circuit 72 does not have the ability to mechanically retain or stabilize the connector 68. Any forces acting between the connector 68 and the flexible circuit 72 could result in damage to the electrical connections critical for operation.
While a strain relief 70, also called a carrier, improves the reliability of this invention, it is not required. Other means such as embedding a flexible wire within the gel may also provide adequate reliability. The preferred embodiment assumes a flexible circuit affixed to a plastic carrier as the most reliable and inexpensive means of bring power from the power receiver module 50 to the host device input connector.
As shown in
The ZIF connector 74 is disclosed as the preferred means of connecting the connection assembly 76 to the power receiver module. Other means are possible within the scope and spirit of this invention. For example, direct soldering may be used to make the necessary attachment. Another means would be a connection attained through loaded metal fingers that slide over the conductors as the connection assembly tip is pressed into a receiving slot. These means fall within the scope and intent of this invention and can be readily done by someone skilled in the art.
The power connector 68 for the target device 20 should protrude as little as possible. Ideally the connector 68 would not protrude from the device it is plugged into farther than the thickness of the gel case 52′ itself. However, this is not always possible. Many times this requirement calls for a custom connector to be manufactured.
The gel-type molded protective cover with embedded wire-free power receiver module can be implemented with a variety of wire-free power transfer technologies. A purpose of gel-type “skin” 52′ is to contain a wire-free power receiver module 50 so that a device 21 can be made compatible with a wire-free power technology by being fitted by such a gel-type skin 52′ with an embedded power receiver 50 and simply plug the connector 68 into a power plug receptacle on the target device 21.
The foregoing description is considered as illustrative of the principles of the invention. Furthermore, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and process shown and described above. Accordingly, resort may be made to all suitable modifications and equivalents that fall within the scope of the invention. The words “comprise,” “comprises,” “comprising,” “include,” “including,” and “includes” when used in this specification are intended to specify the presence of stated features, integers, components, or steps, but they do not preclude the presence or addition of one or more other features, integers, components, steps, or groups thereof.
This application is a nonprovisional application of provisional application No. 61/018,922 filed Jan. 4, 2008, which is incorporated herein by reference.
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