JPH1195922A - Mouse pad, cordless mouse and combination thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make the battery of a cordless mouse maintenance-free. SOLUTION: The mouse pad 10 has a flat surface 10a, on which a cordless mouse 20 moves. The mouse pad 10 is incorporated with a power feeding part for feeding power supplied from a plug 11 to the cordless mouse 20 with no contact. The power feeding part has a frequency converting circuit 12 for converting the supplied power of a commercial frequency from the plug 11 to the converted power of a prescribed frequency, a soft magnetic ferrite board provided in the mouse pad 10, and plural planar helical coils 14 provided on the upper surface of the soft magnetic ferrite board. Then, the planar helical coils 14 are connected so as to mutually invert the directions of magnetic flux of mutually adjacent coils in a certain moment.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a cordless mouse and a mouse pad.

[0002]

2. Description of the Related Art As is well known, a personal computer uses a pointing device as an input device for use in specifying a position on a screen of a display device or instructing coordinate data. A mouse is generally used as the pointing device. A ball (ball) is rotatably attached to the lower surface of the mouse, and a mouse pad may be used to stably rotate the ball. That is, the mouse pad has a flat surface, and when the mouse is moved on this surface, the ball can be smoothly and stably rotated.

By the way, a normal mouse is connected to a computer main body by a cord, but since this cord hinders operation, a cordless mouse has recently been adopted.

In this cordless mouse, information is exchanged with a computer main body using infrared rays.
However, since the cordless mouse is not connected to the computer body by a cord, the cordless mouse itself needs to have a power supply. Conventionally, dry batteries and secondary batteries have been used as the power supply source.

[0005]

As described above, in the conventional cordless mouse, a dry battery or a secondary battery is used as a power supply source. Therefore, when the dry battery runs out or the voltage of the secondary battery decreases. It is necessary to replace the dry batteries or charge the secondary batteries. That is, the conventional cordless mouse requires battery maintenance. During this battery maintenance, the cordless mouse cannot be used.

Accordingly, it is an object of the present invention to provide a cordless mouse having a maintenance-free battery.

Another object of the present invention is to provide a mouse pad which can make a battery of a cordless mouse maintenance-free.

[0008]

Means for Solving the Problems The inventor of the present invention has intensively studied how to make the battery of the cordless mouse maintenance-free. as a result,
The present inventor has noticed that it is only necessary to supply power to the cordless mouse in a non-contact manner. On the other hand, the applicant of the present application has already proposed a “contactless charger” capable of contactlessly charging a secondary battery (for example, Japanese Patent Laid-Open No. 23158/1990).
No. 6). In this non-contact charger, electric power is transmitted from a power transmission side to a power reception side in a non-contact manner using an electromagnetic induction effect.

[0009] The present inventor has thought that this non-contact charger may be applied to supply power to a cordless mouse. As mentioned above, a mouse may be used with a mouse pad. Therefore, if the mouse pad is provided with the power transmission side of the non-contact charger, and the cordless mouse is provided with the power receiving side of the non-contact charger, the battery of the cordless mouse can be made maintenance-free.

That is, according to the present invention, a mouse pad having a flat surface on which a cordless mouse moves can be provided with a plug connected to a commercial power outlet, and the power supplied from the plug is contactless. Thus, a mouse pad having a built-in power transmission means for transmitting power to the cordless mouse can be obtained.

According to the present invention, there is provided a cordless mouse used together with the mouse pad, wherein the cordless mouse includes a power receiving means for receiving power transmitted from the power transmitting means.

[0012]

Since power is transmitted from the mouse pad to the cordless mouse in a non-contact manner, the battery of the cordless mouse is maintenance-free.

[0013]

Next, the present invention will be described in detail with reference to the drawings.

To facilitate understanding of the present invention, a contactless charger will be described first. FIG. 3 shows the configuration of the contactless charger. The non-contact charger includes a power transmission unit 40 for transmitting power, and a power reception unit 50 for receiving power.
The power is transmitted from the power transmitting unit 40 to the power receiving unit 50 in a non-contact manner by using an electromagnetic induction action.

The power transmission section 40 includes a primary ferrite core 41.
And a primary-side PFC board 42, and a primary-side FPC board 4
2 is mounted on the upper surface of the primary ferrite core 41. The illustrated primary ferrite core 41 is soft magnetic, has a weight of 3.4 g, and has a rectangular parallelepiped shape of 38 mm in length and 19 mm in width. A pair of planar spiral coils 43 and 44 and a resonance capacitor 45 are mounted on the primary side FPC board 42. Although not shown, wiring for connecting the pair of planar spiral coils (hereinafter also referred to as spiral coils) 43 and 44 and the resonance capacitor 45 to the primary side FPC board 42 as shown in the figure. Are formed in advance.

Each of the spiral coils 43 and 44 weighs 0.44 g, and the resonance capacitor 45 weighs 60 mg. Here, the spiral coils 43 and 44 are wound so that the directions of the magnetic fluxes generated are opposite to each other, and are connected in series. The spiral coils 43 and 44 connected in series are connected in parallel with the resonance capacitor 45. The resonance frequency defined by the inductance of the spiral coils 43 and 44 and the capacitance Cp of the resonance capacitor 45 is set in the range of 50 kHz to 150 kHz. The reason for this is that outside of this frequency range, circuit losses are high,
This is because noise is generated outside when the resonance frequency is increased. However, if noise can be prevented, the resonance frequency can be increased to about 1 MHz.

As described later, the power transmission section 40 further includes a plug and a frequency conversion circuit.

The power receiving section 50 includes a secondary ferrite core 51.
And a secondary-side FPC board 52.
2 is mounted on the lower surface of the secondary ferrite core 51. The illustrated secondary ferrite core 51 is soft magnetic, weighs 1.7 g, and has a rectangular parallelepiped shape with a length of 38 mm and a width of 19 mm. On the secondary-side FPC board 52, a pair of planar spiral coils 53 and 54, a resonance capacitor 55, a rectifying diode 56, and a smoothing capacitor 57 are mounted. Wiring for connecting the pair of planar spiral coils 53 and 54, the resonance capacitor 45, the rectifying diode 56, and the smoothing capacitor 57 is formed in advance on the secondary-side FPC board 52 as shown in the drawing. .

Each of the spiral coils 53 and 54 weighs 0.44 g, and the resonance capacitor 55 weighs 60 mg. The spiral coils 53 and 54 are respectively
3 and 44, and the spiral coils 43 and
It is wound so that the direction of the current generated by the change of the magnetic flux generated at 44 becomes the same direction, and is connected in series. The spiral coils 53 and 54 connected in series are connected in parallel with the resonance capacitor 55. Spiral coil 5
The resonance frequency defined by the inductances 3, 54 and the capacitance Cs of the resonance capacitor 55 is
The inductance of the spiral coils 43 and 44 in the power transmission unit 40 and the capacitance Cp of the resonance capacitor 45
Is set to be the same as the resonance frequency defined by

The rectifying diode 56 and the smoothing capacitor 57 are connected in series, and are connected in parallel to the resonance capacitor 45. In the illustrated example, the rectifying diode 5
6 weighs 60 mg, and the smoothing capacitor 57 weighs 115 mg. Both ends of the smoothing capacitor 57 are connected to a secondary battery (not shown). Thereby, the secondary battery can be charged without contact.

In the contactless charger having such a configuration, the magnetic flux generated by the spiral coils 43 and 44 at a certain moment
For example, the spiral coil 43 → the primary side ferrite core 41 →
Since the magnetic flux passes through a closed magnetic path including a spiral coil 44 → a spiral coil 54 → a secondary ferrite core 51 → a spiral coil 53 → a spiral coil 43, the magnetic flux can be prevented from leaking to the outside. Therefore, even if the electronic component is arranged close to the secondary ferrite core 51, the electronic component is not heated by the magnetic flux.

FIG. 4 shows a circuit diagram of the contactless charger shown in FIG. The power transmission unit 40 includes a parallel resonance circuit including spiral coils 43 and 44 and a resonance capacitor 45, and a frequency conversion circuit 46 connected to the parallel resonance circuit, and is connected to a commercial power outlet (not shown). Plug 47
Is connected. When the plug 47 is connected to a commercial power outlet, the frequency conversion circuit 46 converts the power supply of the commercial frequency supplied from the plug 47 into converted power of a predetermined frequency equal to that of the parallel resonance circuit. As is well known, such a frequency conversion circuit 46 includes a switching power supply having a built-in oscillator. The parallel resonance circuit functions as a transmitting means for transmitting the converted power to the outside.

The power receiving unit 50 includes a parallel resonance circuit including spiral coils 53 and 54 and a resonance capacitor 55, and a rectification circuit including a rectification diode 56 and a smoothing capacitor 57. That is, the parallel resonance circuit of the power receiving unit 50 functions as a receiving unit that receives power from the transmitting unit of the power transmitting unit 40, and the rectifying circuit of the power receiving unit 50 includes:
The output of the receiving means is converted into DC power.

Referring to FIG. 1, a mouse pad 10 according to an embodiment of the present invention will be described. The illustrated mouse pad 10 has a flat surface 10a,
A cordless mouse (described later) moves above. The mouse pad 10 includes a plug 11 connected to a commercial power outlet (not shown), and has a built-in power transmission unit (described later) for transmitting power supplied from the plug 11 to the cordless mouse in a non-contact manner. ing.

The power transmission unit shown in FIG. 1 includes a frequency conversion circuit 12 that converts power from a commercial frequency supplied from the plug 11 to converted power at a predetermined frequency when the plug 11 is connected to a commercial power outlet. And a plurality of planar spiral coils 14 provided on the upper surface of the soft magnetic ferrite plate (not shown).
And In the illustrated example, the number of the planar spiral coils 14 is (5 × 7), that is, 35. As shown in FIG. 1, the 35 planar spiral coils 14 are spread over the upper surface of the soft magnetic ferrite plate.

Then, the 35 planar spiral coils 14
Are connected such that the directions of the magnetic flux at a certain moment between adjacent ones are opposite to each other. In FIG.
It shows the direction of the magnetic flux when the current I flows in the direction shown in the figure. That is, the symbol “x in ○” indicates the direction of the magnetic flux below the paper surface, and the symbol “• in the ○” indicates the direction of the magnetic flux from below the paper surface. .

FIG. 2 shows a cordless mouse 20 used with the mouse pad 10 shown in FIG. The cordless mouse 20 has a built-in power receiving unit 21 that moves on the surface 10a of the mouse pad 10 and receives power supplied from the power transmitting unit. The configuration of the power receiving unit 21 is shown in FIG.
And the details thereof are omitted.

The cordless mouse 20 has a ball (ball) 22 rotatably mounted on the lower surface thereof.
A light transmitting unit (not shown) for transmitting infrared light to a light receiving unit of a computer main body (not shown) such as a personal computer is provided. The cordless mouse 20 includes a secondary battery (not shown), and the secondary battery is charged by the power receiving unit 21.

By using the mouse pad 10 and the cordless mouse 20 having such a configuration, power is constantly transmitted from the mouse pad 10 to the cordless mouse 20 in a non-contact manner during use. Therefore, cordless mouse 2
Zero battery becomes maintenance-free. In addition, since power is constantly transmitted from the mouse pad 10 to the cordless mouse 20 in a non-contact manner, the cordless mouse 20 may include a capacitor instead of a secondary battery.

In the above embodiment, the mouse pad 10 uses a plurality of planar spiral coils 14 spread on the upper surface of a soft magnetic ferrite plate as a power transmission unit, as shown in FIG. The power transmission unit 40 may be built in a predetermined location (place). In this case, when the rechargeable battery of the cordless mouse 20 needs to be charged, the rechargeable battery is charged by moving the cordless mouse 20 to the above-mentioned predetermined location, and therefore, the charging work is not required.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various changes can be made without departing from the scope of the present invention. Needless to say. For example, the power transmitting means incorporated in the mouse pad and the power receiving means incorporated in the cordless mouse are not limited to the above-described embodiments, and may have any structure as long as it can transmit power in a non-contact manner. .

[0032]

As described above, the mouse pad according to the present invention has a plug connected to a commercial power outlet, and has a power transmitting means for transmitting power supplied from the plug to the cordless mouse in a non-contact manner. Since the cordless mouse according to the present invention has a built-in power receiving means for receiving the power supplied from the power transmitting means, the power can be transmitted from the mouse pad to the cordless mouse in a non-contact manner. Therefore, the battery of the cordless mouse can be made maintenance-free.

[Brief description of the drawings]

FIG. 1 is an internal perspective plan view showing a schematic configuration of a mouse pad according to an embodiment of the present invention.

FIG. 2 is a front view showing a schematic configuration of a cordless mouse used with the mouse pad shown in FIG.

FIG. 3 is an exploded perspective view showing a configuration of a non-contact charger.

FIG. 4 is a circuit diagram of the non-contact charger shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Mouse pad 10a Surface 11 Plug 12 Frequency conversion circuit 14 Flat spiral coil (spiral coil) 20 Cordless mouse 21 Power receiving unit 22 Sphere (ball) 40 Power transmitting unit 41 Primary ferrite core 42 Primary FPC board 43, 44 Flat Spiral coil (spiral coil) 45 Resonant capacitor 46 Frequency conversion circuit 47 Plug 50 Power receiving unit 51 Secondary ferrite core 52 Secondary FPC board 53, 54 Planar spiral coil (spiral coil) 55 Resonant capacitor 56 Rectifier Diode 57 Smoothing capacitor

Claims (13)

[Claims] 1. A mouse pad having a flat surface on which a cordless mouse moves and having a plug connected to a commercial power outlet, and transmitting power supplied from the plug to the cordless mouse in a non-contact manner. A mouse pad having a built-in power transmission means. 2. A cordless mouse used together with the mouse pad according to claim 1, wherein the cordless mouse includes a power receiving unit for receiving power transmitted from the power transmitting unit. 3. The power transmission unit includes: a frequency conversion unit configured to convert a power supply power of a commercial frequency into a conversion power of a predetermined frequency; and a transmission unit having a resonance frequency equal to the predetermined frequency and transmitting the conversion power to the outside. The mouse pad of claim 1, comprising means. 4. The power transmission means according to claim 1, wherein the power transmitting means includes a soft magnetic ferrite plate provided in the mouse pad, and a plurality of planar spiral coils provided on an upper surface of the soft magnetic ferrite plate. Mouse pad as described. 5. The coil according to claim 4, wherein the plurality of planar spiral coils are spread over an upper surface of a soft magnetic ferrite plate.
Mouse pad described in 6. The mouse pad according to claim 4, wherein the plurality of planar spiral coils are connected so that the directions of magnetic flux at a certain moment between adjacent coils are opposite to each other. 7. The power receiving unit has a resonance frequency equal to the predetermined frequency, and includes a receiving unit that receives power from the power transmitting unit, and a rectifying unit that converts an output of the receiving unit into DC power. A cordless mouse according to claim 2. 8. The power receiving means according to claim 2, wherein the power receiving means includes a soft magnetic ferrite plate provided in the cordless mouse, and a plurality of planar spiral coils provided on a lower surface of the soft magnetic ferrite plate. Cordless mouse as described. 9. In a combination of a mouse pad having a flat surface and a cordless mouse that moves on the surface, the mouse pad includes a plug connected to a commercial power outlet, and the power supplied from the plug is used for the mouse pad. A mouse pad and a cordless mouse, wherein the cordless mouse includes a power transmitting unit that transmits power to the cordless mouse in a non-contact manner, and the cordless mouse includes a power receiving unit that receives power supplied from the power transmitting unit. Combinations. 10. The power transmission unit includes: a frequency conversion unit configured to convert a power supply power of a commercial frequency into a converted power of a predetermined frequency; and a transmission unit having a resonance frequency equal to the predetermined frequency and transmitting the converted power to the outside. Means, the power receiving means having a resonance frequency equal to the predetermined frequency, receiving means for receiving the converted power from the transmitting means, and rectifying means for converting the output of the receiving means to DC power The combination of the mouse pad and the cordless mouse according to claim 9, comprising: 11. The power transmission means includes: a pad-side soft magnetic ferrite plate provided in the mouse pad; and a plurality of pad-side planar spiral coils provided on an upper surface of the pad-side soft magnetic ferrite plate. Wherein the power receiving means is provided on a mouse-side soft magnetic ferrite plate provided in the cordless mouse, and is provided on a lower surface of the mouse-side soft magnetic ferrite plate, and is magnetically coupled to the pad-side planar spiral coil. The combination of a mouse pad and a cordless mouse according to claim 9, comprising a plurality of mouse-side flat spiral coils. 12. The combination of a mouse pad and a cordless mouse according to claim 11, wherein the plurality of pad-side planar spiral coils are spread over an upper surface of the pad-side soft magnetic ferrite plate. 13. The plurality of pad-side planar spiral coils are connected so that the directions of magnetic flux at a certain moment between adjacent ones are opposite to each other.
A combination of the mouse pad according to 1 and a cordless mouse.