KR101393707B1 - The wireless mouse with streching and self charging - Google Patents

Abstract

The present invention is to solve problems of a conventional wireless mouse requiring a frequent battery change, of the necessity to have a separate cable for charging and a connector in case of the conventional wireless mouse has a recharging battery, and of the usage inconvenience because a user cannot use a computer while the conventional wireless mouse is being charged. Also, the conventional wireless mouse connected to the computer performs only as a mouse pointer but causes venous thromboembolism and has a limit to be used as an exercising tool. To solve the said problem, the present wireless mouse enabling a user to exercise by stretching comprises the following: a mouse body (10); an induced electromotive force charging unit (20); a light sensor unit (30); an induced electromotive force producing unit (40); a mouse wheel unit (50); a mouse wheel light recognition unit (60); a left omron switching unit (70); a first inclination sensor (80); a right omron switching unit (90); and a second inclination sensor (100). The wireless mouse can be self-charged by generating induced electromotive force to an internal induced coil while a user does a stretching exercise, so that power can be supplied to each device, thereby reducing the energy consumption by 70%. Also, the present invention can prevent venous thromboembolism by enabling the user to do a stretching exercise on shoulders and arms, be used semi-permanently without in need of changing a battery, which is a problem found in the conventional wireless mouse, and prevent malfunctions such as connection failure since the present invention is charged through the induced coil without electric contact to a charging system.

Description

TECHNICAL FIELD [0001] The present invention relates to a wireless mouse capable of self-charging and stretching,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless mouse capable of self-charging and stretching exercises capable of performing a wireless mouse function, a self-charging function through self-induced electromotive force, and a stretching function as a single device.

Currently, a widely used wireless mouse device has a structure in which a mouse device and a computer are not wired, a transmitter is provided on a mouse side, a receiver is connected to a computer, and the mouse movement is transmitted to a computer using wireless communication .

Such a wireless mouse device requires a sensor unit for sensing movement of the mouse and a power source for operating a transmitter for transmitting a signal sensed by the sensor unit.

However, such a conventional wireless mouse has a problem that the battery needs to be replaced frequently because the battery is continuously consumed.

In addition, since the wireless mouse incorporating the battery to be recharged must be equipped with a charging cable and a connector separately, it is not only inconvenient to use during charging, but also disables functionality as a wireless mouse, The computer can not be operated during the charging time, resulting in inconvenience in use.

In addition, the conventional wireless mouse has only a limited role to play a role as a fitness device for solving a disease occurring when using a computer, such as a venous thromboembolism, merely as a mouse pointer connected to a computer.

Korean Registered Utility Model No. 20-0271298

In order to solve the above problems, in the present invention, self-induced electromotive force is generated in an induction coil in an inner part while performing a stretching motion, so that power can be supplied to each device through self-charging so that energy consumption can be efficiently lowered, (Shoulder movement and arm movements), and it can be used semi-permanently without the inconvenience of replacing (or replacing or recharging) the battery, which is a disadvantage of the wireless mouse device. And it is an object of the present invention to provide a well-being wireless mouse capable of self-charging and stretching exercises to prevent malfunction such as connection failure due to charging through an induction coil.

To achieve the above object, a well-being type wireless mouse capable of self-charging and stretching exercises according to the present invention includes:

And self-induced electromotive force is generated in the induction coil in the inside while stretching motion, thereby supplying power to each device through self-charging.

The well-being wireless mouse

A mouse body 10 formed of an elliptical shape and composed of an upper cover and a lower cover to protect each device from external pressure,

An induction electromotive force charging unit 20 which is positioned on the upper cover of the mouse body and receives the induced electromotive force generated in the induction electromotive force unit of the lower cover to charge the charged battery,

A light sensor unit 30 located at one side of the center of the lower cover of the mouse body and sensing left and right movement of the mouse according to the movement of light,

An induction electromotive force generating unit 40 positioned at one side of the optical sensor unit and generating an induced electromotive force,

A mouse wheel 50 positioned at a rear end of the lower cover of the mouse body for rolling the upper and lower positions of the mouse pointer,

A mouse wheel light detecting unit 60 which is positioned on the left and right sides of the mouse wheel unit to shoot light to detect movement of the mouse wheel unit and detects the light passing through the mouse wheel unit to detect the position of the mouse wheel unit,

A left omnon switch part 70 located at one side of the left side of the mouse wheel part and setting a position point on the screen when the mouse is left-clicked,

A first tilt sensor 80 positioned at one side of the repertoon switch and recognizing the left tilt of the mouse wheel,

A light omnon switch unit 90 positioned on the right side of the mouse wheel unit for activating an interface on the screen when the mouse is right-clicked,

And a second tilt sensor (100) positioned at one side of the light ohmonal switch and recognizing the right tilt of the mouse wheel portion.

As described above, according to the present invention, the self-induced electromotive force is generated in the induction coil to supply power to each device through self-charging, thereby lowering the energy consumption by 70%. In addition, And arm motion), it is possible to prevent the pre-venous thromboembolism, and it can be used semi-permanently without the inconvenience of replacing the battery (or replacing or charging the rechargeable battery) and charging through the induction coil without electrical contact to the charging system There is a good effect that a malfunction such as connection failure can be prevented.

1 is a configuration diagram showing components of a well-being wireless mouse 1 capable of self-charging and stretching exercises according to the present invention,
FIG. 2 is a perspective view illustrating components of a well-being type wireless mouse capable of self-charging and stretching exercises according to the present invention;
FIG. 3 is an exploded perspective view showing components of a well-being type wireless mouse capable of self-charging and stretching exercises according to the present invention,
4 is a block diagram illustrating components of an induction electromotive force generating unit according to the present invention.
5 is a block diagram illustrating components of a DC-AC inverter module according to the present invention.
FIG. 6 is a cross-sectional view of a wire rotating induction coil according to the present invention. FIG. 6 is a cross-sectional view illustrating a wire rotating induction coil according to an embodiment of the present invention. In one embodiment,
FIG. 7 is an embodiment showing a stretching exercise with a well-being wireless mouse according to the present invention. FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing components of a well-being type wireless mouse 1 capable of performing a self-charging / stretching motion according to the present invention. In this structure, self-induced electromotive force is generated in an induction coil It supplies power to each device through charging.

The well-being wireless mouse 1 includes a mouse body 10, an induction electromotive force charging unit 20, an optical sensor unit 30, an induction electromotive force generating unit 40, a mouse wheel unit 50, a mouse wheel light sensing unit 60, A left omn switch section 70, a first tilt sensor 80, a light omnon switch section 90, and a second tilt sensor 100.

First, the mouse body 10 according to the present invention will be described.

The mouse body 10 is formed in an elliptical shape and includes a top cover 11 and a bottom cover 12 to protect each device from external pressure.

Next, the induced electromotive force charging unit 20 according to the present invention will be described.

The induction electromotive force charging unit 20 is positioned on the upper cover of the mouse body and receives the induced electromotive force generated in the induction electromotive force unit of the lower cover to charge the rechargeable battery.

It consists of a reception induction coil part 21, a rectifier circuit part 22, a regulator part 23, a current sensing circuit part 24 and a charging control part 25.

The reception induction coil part 21 receives the induced electromotive force generated in the transmission induction coil part.

The rectifying circuit portion 22 serves to rectify the voltage received from the receiving induction coil portion.

It consists of rectifier diodes D1, D2, D3, and D4 consisting of a Schottky diode with fast reverse voltage and fast switching speed.

That is, the AC power flowing into the receiving induction coil through smoothing diodes D1, D2, D3, and D4 is smoothed and rectified, and the rectified AC power is converted from inductor L1 to DC to generate ceramic capacitors C1 and C2 .

The regulator 23 rectifies the voltage received from the reception induction coil to supply 3.3V, 5V power to each device.

This is because the signal input through the receive coil is input to the dual MOSFET and is rectified primarily through the rectifier diode.

The rectified signal is output to each device when the signal is input above the reference voltage through the regulator.

The current sensing circuit unit 24 serves to prevent an overcurrent from flowing into the rechargeable battery 20a to overcharge the rechargeable battery 20a.

It uses an op amp to sense the current flowing to GND.

That is, a signal is input from the GND to the (+) input terminal of the OP amplifier, and the value is compared with the (-) input terminal, and the output is sent to the charge control section.

The charge control unit 25 outputs a charge signal to charge the charged cell according to the current limit and the sensing value transmitted through the current detection circuit unit, reads the battery state of the charged cell, and measures the voltage and current And controls the operation.

This is a place to measure and control the voltage and current to be charged by the charging battery (4.2V) through overcurrent prevention and overcharge prevention. The power input terminal (Pin 1 pin: Vcc) and the short- SHDN) applies a power source (V _in = 5V) through the ceramic capacitor C3 and a timer terminal (pin No. 4: TIMER) sets a timer through a capacitor C4. The ground terminal (pin 5, pin 11: GND) And the NTC terminal (pin 6) are grounded, and the charge current program / charge current monitor terminal (PROG) is configured to check the current charged in the charge battery 33a.

Then, it is set to be inputted to 1.5V through the resistor R1.

The battery terminal (9th pin: BAT) is a place where a charging current (50 mA) flows and the charging battery is charged with a charging voltage of 4.2 V, and a charging battery is formed on one side. Here, the rechargeable battery is made of a lithium ion battery.

Next, the optical sensor unit 30 according to the present invention will be described.

The optical sensor unit 30 is positioned at one side of the center of the lower cover of the mouse body and detects the left and right movement of the mouse according to the movement of the light.

Next, the induced electromotive force generating unit 40 according to the present invention will be described.

The induced electromotive force generating unit 40 is disposed at one side of the optical sensor unit, and generates an induced electromotive force.

4, the buck converter section 41, the Hall effect latch section 42, the DC-AC inverter module 43, the transmission induction coil section 44, the spiral spring section 44, (45), and a stretching portion (46).

First, the buck converter unit 41 according to the present invention will be described.

The buck converter unit 41 converts a voltage lower than the input voltage received from the entire battery and transmits the converted voltage to the DC-AC inverter unit.

It consists of a switch Q ₁ , a diode D ₁ , an output filter L, C, and a load resistor R using a MOSFET.

That is, when the switching element is ON, the input voltage is transferred to the output voltage, and when the switching element is OFF, the energy is transferred to the output through the diode.

The power supply voltage V _i is applied to the drain of the N-MOSFET.

In a period in which the PWM waveform applied to the gate is high, the MOSFET becomes on-state, and a current flows from the drain to the source.

 A power source inputted through a source is a high frequency signal because it is a power source signal inputted with a high signal applied to a gate for a short time.

The high-frequency signal is passed through a low-pass filter composed of L and C, and the high-frequency component is removed, and the output voltage V0 is outputted through the load.

When L and C are in a buffered state during on-time, a low signal is applied to the gate signal of the MOSFET to turn off the input power to turn it off-state.

At this time, the energy stored in the inductor starts discharging and acts as an input power even though it is instantaneous, thereby continuously supplying power to the load. At this time, a diode is configured to generate a close-loop.

The ON / OFF operation of Q ₁ is repeated with the switching period T _s as one cycle, and the input voltage is converted into a desired output voltage.

Second, a Hall effect latch unit 42 according to the present invention will be described.

The Hall effect latch unit 42 recognizes magnetic induction between electromagnetic induction between the transmission induction coil part and the reception induction coil part to convert the idle state to the wakeup state.

This charges the rechargeable battery of the top cover using the induced power when the sending and receiving coils are self-aligned.

In the present invention, the wake-up operation of the system operates by detecting a Hall effect through a Hall effect latch.

That is, when a current is applied to both ends of a metal or a semiconductor and a magnetic field is vertically applied thereto, electrons or holes are biased in a direction perpendicular to the current and magnetic field by the Lorentz force.

At this time, a potential difference is generated at both ends of the metal or semiconductor by the moving charge, and an electric field is formed in the inside to generate an electric force in a direction opposite to the Lorentz force.

When the force received by this electric field and the Lorentz force are in equilibrium, the charge is no longer biased, and the current flows in the direction in which the current first flowed. In this case, the difference in potential generated between the metal and the semiconductor is proportional to the magnitude of the magnetic field Is called a Hall effect.

At this time, if the voltage generated by the Hall effect is V _H and the Hall coefficient, which is a proportional constant, is R _H , the relational expression between the magnetic field B and the Hall voltage V _H is expressed as Equation 1 below.

[ Equation 1 ]

V _H = R _H / t * IB

In Equation 1, I is the current applied to the hole specimen, and t is the thickness of the specimen. The Hall coefficient (R _H ) is expressed by the following equation (2).

& Quot; (2 ) & quot ;

R _H = μ / σ, R _H = 1 / ne

Where micro is the electron mobility, row is the electrical conductivity, and n is the density of the charge.

The mobility and density of the charge can be determined by calculating the Hall coefficient R _H through Equation (2), and the type of the charge can be known by the sign of the Hall voltage. The Hall voltage is determined by the intensity of the magnetic field.

That is, when the current and the magnetic field are inclined rather than perpendicular to each other, the component of the vertical magnetic field is effective. As a result, the Hall voltage is proportional to the sin theta with respect to the angle (theta) between the current and the magnetic field.

Third, the DC-AC inverter module 43 according to the present invention will be described.

The DC-AC inverter module 43 converts the DC voltage converted through the buck converter part into an AC voltage, and transmits the induced electromotive force generated in the transmission induction coil part to the induced electromotive force charging part.

Herein, the transmission of the induced electromotive force to the induced electromotive force charging section means that the induced electromotive force is radiated into the air to generate the induced electromotive force in the receiving induction coil of the induced electromotive force charging section.

As shown in FIG. 5, the dual MOSFET driver 43a includes a dual MOSFET driver 43a, a transmission controller 43b, and a timer 43c.

The dual MOSFET driver 43a serves as a single-phase gate driver that operates and optimizes the high-side gate and the low-side gate of the buck converter.

The transmission control unit 43b receives the charging continuity signal from the timer unit to the induction electromotive force charging unit and controls the dual MOSFET driver to be driven and controls the induction electromotive force charging unit to output the induction electromotive force transmission output signal. And controls the overall operation of the apparatus.

The timer 43c receives information on the remaining battery power of the rechargeable battery from the induction electromotive force recharging unit and transmits the remaining information to the controller.

Fourth, the transmission induction coil part 44 according to the present invention will be described.

The transmission-inducing coil part 44 receives the (+) (-) power from the rechargeable battery and serves to generate the induction electromotive force primarily in the spiral-shaped wire rotation induction coil.

This is constructed by coating ferrite around the wire rotation induction coil.

The ferrite used in the present invention is a magnetic material having a frequency of 5 kHz to 2 MHz and a capacity of 5 W to 100 W, It is formed of a thin sheet of steel and is properly attached to the mouse pad.

These ferrites have lower thermal resistance than existing winding transformers, and can reduce the weight and size of the winding products more than the conventional products (approx. 1cc per 40W), and the efficiency is improved by 10% And low leakage inductance and electromagnetic interference are minimized.

Fifth, the spiral spring portion 45 according to the present invention will be described.

The spiral spring portion 45 is formed at one side of the center of the wire rotation induction coil and is rotated by the rotation of the wire to generate the second-order induced electromotive force.

As shown in FIG. 6, when the wire is wound around the metal turning drum 45a by the stretching part while being unwound and rotated, the metal turning formed on one side of the center of the wire turn induction coil is rotated, To generate an induced electromotive force.

Sixth, the stretching part 46 according to the present invention will be described.

The stretching part 46 serves to assist in arm movement and shoulder movement while reducing and increasing the number of wires connected to the spiral spring part.

It consists of a wire and a finger ring.

Next, the mouse wheel 50 according to the present invention will be described.

The mouse wheel 50 is positioned at a rear end of the lower cover of the mouse body and serves to roll the upper and lower positions of the mouse pointer.

Next, the mouse wheel light detecting unit 60 according to the present invention will be described.

The mouse wheel light detecting unit 60 is positioned at left and right sides with respect to the mouse wheel unit to shoot light in order to detect movement of the mouse wheel unit and detects light passing through the mouse wheel unit to detect the position of the mouse wheel unit .

The encoder is configured to read the movement of the mouse wheel and express it as a two-dimensional Cartesian coordinate system.

Next, the left omnon switch unit 70 according to the present invention will be described.

The left omnon switch unit 70 is located on the left side of the mouse wheel unit and sets a position point on the screen when the mouse is left-clicked.

Next, the first tilt sensor 80 according to the present invention will be described.

The first tilt sensor 80 is located at one side of the re fl omron switch and recognizes the left tilt of the mouse wheel.

Next, the write-ohmonal switch unit 90 according to the present invention will be described.

The light-ohmon switch unit 90 is located on the right side of the mouse wheel unit and activates the interface on the screen when the mouse is right-clicked.

Next, the second tilt sensor 100 according to the present invention will be described.

The second tilt sensor 100 is located at one side of the light omnison switch and recognizes the right tilt of the mouse wheel.

Hereinafter, a specific operation process of the well-being wireless mouse capable of self-charging and stretching motion according to the present invention will be described.

[ Well-being type  Overall Operation of Wireless Mouse]

First, the induced electromotive force generating unit 20 receives the induced electromotive force generated in the induced electromotive force unit of the lower cover to charge the charged battery.

Next, the optical sensor unit 30 detects the left and right movement of the mouse according to the movement of the light.

Next, the induced electromotive force generating unit 40 generates an induced electromotive force.

Next, the mouse wheel 50 rotates the vertical position of the mouse pointer.

Next, the mouse wheel light detecting unit 60 shoots light to detect movement of the mouse wheel unit, detects light passing through the mouse wheel unit, and detects the position of the mouse wheel unit.

Next, when the left mouse button is clicked in the left omnon switch unit 70, a position point is set on the screen.

Next, the first tilt sensor 80 recognizes the left tilt of the mouse wheel portion.

Next, when the right-clicked on the light-ohmonal switch unit 90 is clicked, the interface is activated on the screen.

Finally, the second tilt sensor 100 recognizes the right tilt of the mouse wheel portion.

[With self-charging function Well-being type  Wireless mouse]

First, a positive (+) (-) power source is supplied from the charging cell in the transmission induction coil part 44, and the induction electromotive force is firstly generated in the spirally formed wire rotation induction coil.

Next, the wire is rotated by the rotation of the wire at the spiral spring portion, thereby generating an induced electromotive force in a second order.

That is, when the wire is rotated while being unwound by the stretching part on the basis of the metal spinning reel, the metal rotating body formed on one side of the center of the wire rotation inducing coil is rotated to induce electromagnetic induction phenomenon to generate induced electromotive force.

Next, the buck converter converts a voltage lower than the input voltage received from the rechargeable battery into a DC-AC inverter unit.

Next, in the Hall effect latch unit 42, the magnetic matrix due to the electromagnetic induction between the transmission-inducing coil part and the reception-inducing coil part is recognized and switched from the idle state to the wake-up state.

Next, the DC-AC inverter module converts the DC voltage converted through the buck converter section to the AC voltage, and then transmits the induced electromotive force generated in the transmission induction coil section to the induced electromotive force charging section.

Next, the induced electromotive force generated in a part of the transmission induction coil is received through the reception induction coil part.

Next, in the rectifying circuit section, the voltage received from the receiving induction coil section is rectified.

Next, the regulator unit rectifies the voltage received from the receiving induction coil part to supply 3.3V, 5V power to each device.

Next, it is prevented that the overcurrent flows into the rechargeable battery in the current sensing circuit portion to overcharge.

Finally, under the control of the charge control unit, the charge signal is outputted so that the charge cell is charged according to the current limit of the charge cell and the sensing value transmitted through the current detection circuit unit, the battery state of the charge cell is read, .

[Cordless mouse with stretching function]

First, the wire wound around the spiral spring portion is stretched through the stretching portion.

Next, the mouse body is held on the left side of the user, and the stretching part is gripped on the right side of the user to perform the arm movement and the shoulder movement.

Finally, as shown in FIG. 7, during the arm movement and the shoulder movement, the arm connected to the spiral spring portion is stretched and reduced through the stretching portion, and arm movement and shoulder movement are performed.

At this time, when the wire is wound around the metal turning by the stretching part and rotated while being rotated, the metal turning formed on one side of the center of the wire rotation induction coil is rotated to induce electromagnetic induction phenomenon to generate induction electromotive force.

1: Well-being wireless mouse 10: Mouse body
20: Inductive electromotive force charging unit 30: Light sensor unit
40: induction electromotive force generating unit 50:
60: Mouse wheel light detecting unit 70: Left omn switch unit
80: first tilt sensor 90: light omn switch part
100: second tilt sensor

Claims (5)

The present invention relates to a well-being type wireless mouse capable of performing self-charging and arm movement by self-induction electromotive force generated in an induction coil therein while supplying power to each device through self-
The well-being wireless mouse
A mouse body 10 formed of an elliptical shape and composed of an upper cover and a lower cover to protect each device from external pressure,
An induction electromotive force charging unit 20 which is positioned on the upper cover of the mouse body and receives the induced electromotive force generated in the induction electromotive force unit of the lower cover to charge the charged battery,
A light sensor unit 30 located at one side of the center of the lower cover of the mouse body and sensing left and right movement of the mouse according to the movement of light,
An induction electromotive force generating unit 40 positioned at one side of the optical sensor unit and generating an induced electromotive force,
A mouse wheel 50 positioned at a rear end of the lower cover of the mouse body for rolling the upper and lower positions of the mouse pointer,
A mouse wheel light detecting unit 60 which is positioned on the left and right sides of the mouse wheel unit to shoot light to detect movement of the mouse wheel unit and detects the light passing through the mouse wheel unit to detect the position of the mouse wheel unit,
A left omnon switch part 70 located at one side of the left side of the mouse wheel part and setting a position point on the screen when the mouse is left-clicked,
A first tilt sensor 80 positioned at one side of the repertoon switch and recognizing the left tilt of the mouse wheel,
A light omnon switch unit 90 positioned on the right side of the mouse wheel unit for activating an interface on the screen when the mouse is right-clicked,
And a second tilt sensor (100) located at one side of the light ohmonal switch and recognizing a right tilt of the mouse wheel.
delete [3] The apparatus according to claim 1, wherein the induced electromotive force charging unit (20)
A reception induction coil part 21 receiving an induced electromotive force generated in a part of the transmission induction coil,
A rectifying circuit section (22) for rectifying the voltage received from the reception induction coil section,
A regulator 23 for rectifying the voltage received from the reception induction coil and supplying 3.3 V, 5 V power to each device,
A current sensing circuit part (24) for preventing an overcurrent from flowing into the rechargeable battery and overcharging,
A charging controller 25 for outputting a charging signal so that the charging battery is charged according to the sensing value transmitted through the current sensing circuit unit, reading the battery state of the charging battery, and measuring and controlling the voltage and current, The portable wireless mouse according to claim 1,
The induction generator according to claim 1, wherein the induction electromotive force generating unit (40)
A buck converter unit 41 for converting a voltage lower than the input voltage received from the rechargeable battery and delivering the voltage to the DC-AC inverter unit,
A Hall effect latch unit 42 for recognizing the magnetic matrix due to electromagnetic induction between a part of the transmission induction coil and the reception induction coil part to mutually recognize the wakeup state from the idle state,
A DC-AC inverter module 43 for converting the DC voltage converted through the buck converter part to an AC voltage and transmitting the induced electromotive force generated in the transmission induction coil part to the induced electromotive force charging part,
A transmission induction coil part 44 for generating a first induction electromotive force in a spirally formed wire rotation induction coil by receiving (+) (-) power from the rechargeable battery,
A spiral spring portion 45 formed at one side of the center of the wire rotation induction coil and rotated by rotation of the wire to generate an induced electromotive force in a second order,
And a stretching part (46) for stretching and reducing the wire connected to the spiral spring part and assisting in arm movement and shoulder movement.
5. The DC-AC inverter module (43) according to claim 4, wherein the DC-AC inverter module
A dual MOSFET driver 43a that operates a high-side gate and a low-side gate of the buck converter and serves as a single-phase gate driver,
And a controller for controlling the dual MOSFET driver to drive the dual MOSFET driver and to output the induction electromotive force transmission output signal to the induction electromotive force charging unit, A control unit 43b,
And a timer unit (43c) for receiving information on the battery remaining amount of the rechargeable battery from the induced electromotive force recharging unit and delivering the remaining charge to the control unit.

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