TWI583111B - Micro vibra power generator and control method thereof - Google Patents

Description

Micro vibration generator and its control method

The present invention relates to a vibration generator and a control method thereof, and more particularly to a micro-vibration generator that transmits instantaneous large-scale electric power through a rapid magnetic field change and a control method thereof.

In modern life, there are many portable electronic components with batteries, such as remote controls, flashlights, and mobile phones. Current portable electronic components, whether rechargeable or non-rechargeable, are powered by batteries. However, general batteries have a useful life regardless of whether they are rechargeable or not. Moreover, since the average user does not have the habit of checking the battery capacity at regular intervals, when these portable electronic components are required, it is often found that the battery is dead or leaking, and even if the rechargeable battery has failed to supply power normally, it cannot be used immediately. Portable electronic parts. In addition, in view of the fact that portable electronic components need to be equipped with batteries in order to operate electronic components, it is neither environmentally friendly nor convenient, and users often encounter the dilemma of dead batteries and need to go out to buy batteries, if it is in the early hours of the morning. At the same time, it will feel unsafe, which will greatly affect the ease of use and practicality of the product.

In order to solve the above problem, a conventional vibration generator provides short-term power through a hand pressure or a hand-cranked power generator. Although the conventional vibration generator utilizes an artificial manual method to press or shake the vibration generator, the magnetic member inside the vibration generator can be displaced to generate electric power, but the vibration generator is often used because of the force or hand of the hand. The frequency of the shake differs from the amount of displacement to produce different power. Moreover, when the hand is shaken for a period of time, the user will slow down the magnetic field change due to the smaller force, and the power will also become smaller. It can be seen that there is a lack of a micro-vibration generator and its control method for stably providing power without large pressing or shaking, so the relevant operators are seeking solutions.

Accordingly, the present invention provides a micro-vibration generator and a method of controlling the same that utilizes a change in a magnetic field to generate short-term power and supply it to an electronic component, thereby avoiding the dilemma of the battery being out of power and being unable to use the electronic component. Furthermore, the two ends of the third magnetically permeable metal can be quickly switched by the special shape of the magnetically permeable metal. As the travel distance is reduced, the metal tends to accelerate the travel speed due to the change of the magnetic field, further making the magnetic field change faster, and at the same time making the power generation more high. In addition, the special mechanism of the micro-vibration generator combined with the corresponding control method can minimize the impact of hand pressure or hand crank.

According to a structural aspect of the present invention, a micro vibration generator including a magnetic member, a first magnetic conductive metal, a second magnetic conductive metal, and a third magnetic conductive metal is provided. The magnetic member includes a first magnetic pole and a second magnetic pole. the first The magnetically conductive metal is connected to the first magnetic pole. The second magnetic conductive metal is connected to the second magnetic pole, and the second magnetic conductive metal is spaced apart from the first magnetic conductive metal by a distance. The third magnetic conductive metal includes a first switching end and a second switching end, and the first switching end and the second switching end are reciprocally displaced to switch between the first magnetic conductive metal and the second magnetic conductive metal. In addition, when the first switching end is connected to the first magnetic conductive metal, the second switching end is connected to the second magnetic conductive metal.

Thereby, the micro-vibration generator of the present invention utilizes a change in the magnetic field to generate a short-term power and supply it to the electronic component, thereby avoiding the dilemma of the battery being dead and using the electronic component. In addition, through the special shape of the magnetic conductive metal and the reduced displacement path, the two ends of the third magnetic conductive metal can be quickly switched between the magnetic levels, and the third magnetic conductive metal accelerates the traveling speed due to the rapid change of the magnetic field, thereby greatly increasing the power generation. Power.

According to the aforementioned micro-vibration generator, the first magnetic conductive metal may include a first guide pin and a second guide pin. The second magnetically conductive metal includes a first contact pin and a second contact pin. The first switching end is disposed between the first guiding pin and the first contact pin, and the second switching end is disposed between the second guiding pin and the second contact pin. The first lead pin is separated from the first contact pin by a first switching pitch, and the second lead pin is separated from the second contact pin by a second switching pitch, and the first switching pitch is equal to the second switching pitch. In addition, when the first switching end is connected to the first guiding pin, the second switching end is connected to the second contact pin. The cross sections of the first magnetic conductive metal, the second magnetic conductive metal and the third magnetic conductive metal are all concave. The first magnetically permeable metal includes a first recess, the second magnetically permeable metal includes a second recess, and the third magnetically permeable metal includes a third recess. The orientation of the first recess is the same as the orientation of the second recess, the orientation of the first recess being opposite to the orientation of the third recess. In addition, the aforementioned micro vibration power generation The machine can be used to supply power to electronic components, including conductive metal wires and voltage regulator circuits. The conductive metal wire surrounds the third magnetic conductive metal to form a plurality of cylindrical bodies. The voltage stabilizing circuit is connected to the conductive metal wire, and the conductive metal wire provides a current to the voltage stabilizing circuit, so that the voltage stabilizing circuit supplies the voltage to the electronic component.

According to another structural aspect of the present invention, a micro vibration generator including a magnetic member, a first magnetic conductive metal, a second magnetic conductive metal, and a third magnetic conductive metal is provided. The magnetic member includes a first magnetic pole and a second magnetic pole. The first magnetically conductive metal is connected to the first magnetic pole. The second magnetic conductive metal is connected to the second magnetic pole, and the second magnetic conductive metal is spaced apart from the first magnetic conductive metal by a distance. The third magnetic conductive metal includes a first switching end and a second switching end, and the first switching end and the second switching end are reciprocally displaced to switch between the first magnetic conductive metal and the second magnetic conductive metal. Furthermore, when the first switching end is connected to the second magnetic conductive metal, the second switching end is connected to the first magnetic conductive metal.

Thereby, the micro-vibration generator of the present invention utilizes a change in the magnetic field to generate a short-term power supply for the operation of the electronic component, thereby avoiding the dilemma in which the battery is dead and the electronic component cannot be used. In addition, the rapid change of the transmitted magnetic field can greatly increase the power of power generation.

According to the aforementioned micro-vibration generator, the first magnetic conductive metal may include a first guiding pin and a second guiding pin, and the second magnetic conductive metal comprises a first contact pin and a second contact pin. The first switching end is disposed between the first guiding pin and the first contact pin, and the second switching end is disposed between the second guiding pin and the second contact pin. The first lead is spaced apart from the first contact by a first switching pitch, and the second lead is spaced apart from the second contact by a second switching pitch, the first switching pitch being equal to the second switching pitch. when When the first switching end is connected to the first contact pin, the second switching end is connected to the second lead pin. In addition, the cross-sections of the first magnetic conductive metal, the second magnetic conductive metal, and the third magnetic conductive metal are all concave. The first magnetically permeable metal includes a first recess, the second magnetically permeable metal includes a second recess, and the third magnetically permeable metal includes a third recess. The orientation of the first recess is the same as the orientation of the second recess, and the orientation of the first recess is opposite to the orientation of the third recess. In addition, the aforementioned micro-vibration generator can be used to supply power to an electronic component including a conductive metal wire and a voltage stabilizing circuit. The conductive metal wire surrounds the third magnetic conductive metal to form a plurality of cylindrical bodies. The voltage stabilizing circuit is connected to the conductive metal wire, and the conductive metal wire provides a current to the voltage stabilizing circuit, so that the voltage stabilizing circuit supplies the voltage to the electronic component.

According to a method aspect of the present invention, a method for controlling a micro-vibration generator is provided, which includes a first manipulation step and a second manipulation step. The first control step is to set the first switching pitch and the second switching pitch of the first magnetic conductive metal and the second magnetic conductive metal, and set the first switching end and the second switching end of the third magnetic conductive metal respectively The first switching pitch is between the second switching pitch. The second manipulation step is to limit the displacement of the third magnetic conductive metal between the first magnetic conductive metal and the second magnetic conductive metal, and control the first switching end and the second switching end to be detachably connected to the first magnetic conductive metal. And the second magnetic conductive metal, causing the magnetic pole of the first switching end and the magnetic pole of the second switching end to alternately switch.

Thereby, the control method of the micro-vibration generator of the present invention not only minimizes the influence of hand pressure or hand shake through the control mode of the special mechanism, but also provides relatively stable power to avoid the traditional hand pressure or hand crank. The micro-vibration generator generates different electric power due to the different force of the user's control.

According to the foregoing control method of the micro-vibration generator, a third manipulation step may be included, which comprises forming a plurality of cylindrical bodies by surrounding a third magnetic conductive metal with a conductive metal wire, and the conductive metal wire is coated on the conductive metal wire. The middle portion of the third magnetically permeable metal. Furthermore, the aforementioned micro-vibration generator control method may include a fourth control step of supplying current to the voltage stabilizing circuit through the conductive metal wire, so that the voltage stabilizing circuit supplies voltage to the electronic component.

100, 100a‧‧‧Micro-vibration generator

200, 200a‧‧‧ magnetic parts

210‧‧‧First magnetic pole

220‧‧‧second magnetic pole

300‧‧‧First magnetically permeable metal

310‧‧‧First lead

320‧‧‧Second lead

400, 400a‧‧‧Second magnetic metal

410‧‧‧First foot

420‧‧‧Second foot

500‧‧‧ Third magnetically permeable metal

510‧‧‧ first switch end

520‧‧‧Second switching end

600‧‧‧conductive metal wire

610‧‧‧ columnar body

700‧‧‧Variable circuit

710‧‧‧Electronic parts

800‧‧‧Manipulation method of micro-vibration generator

800a‧‧‧Micro-vibration generator control method

N, S‧‧‧ magnetic pole

T‧‧‧ spacing

D1‧‧‧ first switching pitch

D2‧‧‧Second switching pitch

S11, S21‧‧‧ first control steps

S12, S22‧‧‧ second control steps

S23‧‧‧ third control step

S24‧‧‧ fourth control step

Fig. 1 is a schematic view showing a micro-vibration generator according to an embodiment of the present invention.

Fig. 2 is a schematic view showing a micro-vibration generator of an embodiment of the embodiment of Fig. 1.

Fig. 3 is a schematic view showing a micro-vibration generator of another embodiment of the embodiment of Fig. 1.

Fig. 4 is a schematic view showing a micro-vibration generator according to another embodiment of the present invention.

FIG. 5 is a flow chart showing a method of controlling a micro-vibration generator according to an embodiment of the present invention.

FIG. 6 is a schematic flow chart showing a method of controlling a micro-vibration generator according to an embodiment of the fifth embodiment.

Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. For the sake of clarity, many practical details will be explained in the following description. However, it should be understood that these practical details are not intended to limit the invention. That is, in some embodiments of the invention, these practical details are not necessary. In addition, some of the conventional structures and elements are illustrated in the drawings in a simplified schematic manner, and the repeated elements may be represented by the same reference numerals.

Fig. 1 is a schematic view showing a micro-vibration generator 100 according to an embodiment of the present invention. Fig. 2 is a schematic view showing a micro-vibration generator 100 according to an embodiment of the embodiment of Fig. 1. Fig. 3 is a schematic view showing a micro-vibration generator 100 according to another embodiment of the embodiment of Fig. 1. As shown, the micro-vibration generator 100 is used to supply power to an electronic component 710, which can be a general mobile device, a radio frequency transmission electronic component, or a portable electronic product. The micro-vibration generator 100 includes a magnetic member 200, a first magnetic conductive metal 300, a second magnetic conductive metal 400, a third magnetic conductive metal 500, a conductive metal wire 600, and a voltage stabilizing circuit 700.

The magnetic member 200 includes a first magnetic pole 210, a second magnetic pole 220, and a thickness. The first magnetic pole 210 may be a magnetic pole N or a magnetic pole S, and the second magnetic pole 220 may be a magnetic pole S or a magnetic pole N. The two magnetic poles are opposite to each other, and the first magnetic pole 210 of the embodiment is a magnetic pole N, and the second magnetic pole 220 is a magnetic pole S. The magnetic member 200 is a permanent magnet. The thickness is the distance between the ends of the first magnetic pole 210 and the second magnetic pole 220.

The first magnetic conductive metal 300 is connected to the first magnetic pole 210, and the first magnetic conductive metal 300 may include a first guiding pin 310, a second guiding pin 320 and a first notch. The cross section of the first magnetically permeable metal 300 has a concave shape, and the first notch faces the negative direction of the Y axis.

The second magnetic conductive metal 400 is connected to the second magnetic pole 220, and the second magnetic conductive metal 400 is spaced apart from the first magnetic conductive metal 300 by a distance T which is equal to the thickness of the magnetic member 200. The second magnetic conductive metal 400 includes a first contact 410, a second contact 420, and a second recess. The cross section of the second magnetic conductive metal 400 is concave, and the second recess is oriented in the negative direction of the Y axis. In other words, the orientation of the second recess is the same as the orientation of the first recess. In addition, the length of the first magnetic conductive metal 300 is greater than the length of the second magnetic conductive metal 400, and the cross-sectional area of the first magnetic conductive metal 300 is also larger than the cross-sectional area of the second magnetic conductive metal 400.

The third magnetic conductive metal 500 includes a first switching end 510, a second switching end 520, and a third notch. The cross section of the third magnetic conductive metal 500 is concave and the third notch faces the positive direction of the Y axis. The orientation of the third recess is opposite to the orientation of the first recess. The first switching end 510 and the second switching end 520 are reciprocally displaced to switch between the first magnetic conductive metal 300 and the second magnetic conductive metal 400. In detail, the first switching end 510 of the third magnetic conductive metal 500 is disposed between the first lead leg 310 of the first magnetic conductive metal 300 and the first contact pin 410 of the second magnetic conductive metal 400, and the second switching The end 520 is disposed between the second lead 320 and the second contact 420. The first guiding pin 310 is separated from the first contact pin 410 by a first switching pitch D1, and the second guiding pin 320 is separated from the second contact pin 420 by a second switching pitch D2, and the first switching pitch D1 is equal to The second switching pitch D2. In addition, the length of the third magnetic conductive metal 500 is between the length of the first magnetic conductive metal 300 and the length of the second magnetic conductive metal 400. Moreover, when the first switching end 510 is connected to the first guiding pin 310 of the first magnetic conductive metal 300, the second switching end 520 is connected to the second contact pin 420 of the second magnetic conductive metal 400; conversely, when the first switching is performed When the terminal 510 is connected to the first contact pin 410 of the second magnetic conductive metal 400, the second switching end 520 is connected to the second guiding pin 320 of the first magnetic conductive metal 300. The present invention utilizes rapid changes in the magnetic field to generate short-lived power and supply it to the electronic component 710, which avoids the problem of the battery being out of power and the inability to use the electronic component 710.

The conductive metal wire 600 surrounds the intermediate portion of the third magnetic conductive metal 500 to form a plurality of turns of the columnar body 610. The columnar body 610 of the present embodiment is formed by winding the conductive metal wire 600 around a hundred turns, and the magnetic poles passing through the two ends of the third magnetic conductive metal 500 are rapidly changed, so that the conductive metal wire 600 generates a short current for the electronic components at the rear end. 710 is used.

The voltage stabilizing circuit 700 connects the conductive metal line 600 and the electronic component 710. When the magnetic pole of the third magnetic conductive metal 500 changes, the conductive metal wire 600 supplies current to the voltage stabilizing circuit 700, so that the voltage stabilizing circuit 700 provides a stable voltage to the electronic component 710. Therefore, the present invention can quickly switch both ends of the third magnetic conductive metal 500 through the special shape and structure of the first magnetic conductive metal 300 and the second magnetic conductive metal 400. Since the traveling distance of the third magnetic conductive metal 500 is reduced, the third magnetic conductive metal 500 is liable to accelerate the traveling speed due to the change of the magnetic field, further making the magnetic field change faster, and at the same time making the power generation more high.

Fig. 4 is a schematic view showing a micro-vibration generator 100a according to another embodiment of the present invention. The micro-vibration generator 100a includes a magnetic member 200a, a first magnetic conductive metal 300, a second magnetic conductive metal 400a, a third magnetic conductive metal 500, a conductive metal wire 600, and a voltage stabilizing circuit 700. Referring to FIG. 1 and FIG. 4, the first magnetic conductive metal 300, the third magnetic conductive metal 500, the conductive metal wire 600, and the voltage stabilizing circuit 700 are respectively the same as those in the first embodiment, and are not described again. . In particular, the magnetic member 200a of the embodiment of FIG. 4 and the magnetic member 200 of the first embodiment are opposite magnetic poles, and the shape of the transverse surface of the second magnetic conductive metal 400a is elongated, which is the second guide of FIG. The concave shape of the magnetic metal 400 is different. It can be seen that the present invention can realize the same rapid change effect of the magnetic field by different structures, and the manufacturing cost of the micro-vibration generator 100a can be further reduced by using the elongated second magnetic conductive metal 400a.

Referring to FIG. 1 , FIG. 5 is a schematic flow chart of a method 800 for controlling a micro-vibration generator according to an embodiment of the present invention. As shown, the micro-vibration generator control method 800 includes a first manipulation step S11 and a second manipulation step S12. The first control step S11 sets the first magnetic conductive metal 300 and the second magnetic conductive metal 400 to the same first switching pitch D1 and the second switching pitch D2, and the first switching end 510 of the third magnetic conductive metal 500. The second switching end 520 is disposed between the first switching pitch D1 and the second switching pitch D2, respectively. The second control step S12 is to limit the displacement of the third magnetic conductive metal 500 between the first magnetic conductive metal 300 and the second magnetic conductive metal 400, and the first switching end 510 is detachably connected to the second switching end 520. The first magnetic conductive metal 300 and the second magnetic conductive gold The genus 400 causes the magnetic poles of the first switching end 510 to alternately switch with the magnetic poles of the second switching end 520. In addition, the above-described micro-vibration generator control method 800 can also be applied to the micro-vibration generator 100a of FIG. 4, and the steps are the same, and therefore will not be described again. Thereby, the present invention can minimize the influence of hand pressure or hand shake through the special mechanism of the micro-vibration generators 100, 100a and the corresponding control method.

FIG. 6 is a schematic flow chart showing a method 800a for controlling a micro-vibration generator according to an embodiment of the fifth embodiment. The micro vibration generator control method 800a includes a first manipulation step S21, a second manipulation step S22, a third manipulation step S23, and a fourth manipulation step S24. The first control step S21 and the second control step S22 are the same as the first control step S11 and the second control step S12 of FIG. 5, respectively, and are not described again. In particular, the embodiment of FIG. 6 further includes a third manipulation step S23 and a fourth manipulation step S24. The third control step S23 is performed by forming a plurality of turns of the columnar body 610 around the third conductive metal 500 by using a conductive metal wire 600, and the conductive metal wire 600 is wrapped around the middle portion of the third conductive metal 500. . Furthermore, the fourth manipulation step S24 supplies current to the voltage stabilizing circuit 700 through the conductive metal line 600, so that the voltage stabilizing circuit 700 supplies a voltage to the electronic component 710. Through the above steps, a stable and sufficient voltage can be supplied for the electronic component 710 to operate.

As can be seen from the above embodiments, the present invention has the following advantages: First, the use of rapid changes in the magnetic field to generate short-term power and supply to the electronic components can avoid the dilemma of the use of electronic components without the battery being dead. Second, through the special shape of the magnetically permeable metal, two of the third magnetically permeable metals can be made. The terminal switches quickly. As the travel distance is reduced, the metal tends to accelerate the travel speed due to the change of the magnetic field, further making the magnetic field change faster, and at the same time making the power generation more high. Third, the special mechanism of the micro-vibration generator can be combined with the corresponding control method to minimize the impact of hand pressure or hand crank.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and the present invention can be modified and modified without departing from the spirit and scope of the present invention. The scope is subject to the definition of the scope of the patent application attached.

100‧‧‧Micro-vibration generator

200‧‧‧Magnetic parts

210‧‧‧First magnetic pole

220‧‧‧second magnetic pole

300‧‧‧First magnetically permeable metal

310‧‧‧First lead

320‧‧‧Second lead

400‧‧‧Second magnetic metal

410‧‧‧First foot

420‧‧‧Second foot

500‧‧‧ Third magnetically permeable metal

510‧‧‧ first switch end

520‧‧‧Second switching end

600‧‧‧conductive metal wire

610‧‧‧ columnar body

700‧‧‧Variable circuit

710‧‧‧Electronic parts

N, S‧‧‧ magnetic pole

T‧‧‧ spacing

D1‧‧‧ first switching pitch

D2‧‧‧Second switching pitch

Claims (13)

A micro-vibration generator comprising: a magnetic member comprising a first magnetic pole and a second magnetic pole; a first magnetic conductive metal connecting the first magnetic pole; and a second magnetic conductive metal connecting the second magnetic pole, The second magnetic conductive metal is spaced apart from the first magnetic conductive metal; and a third magnetic conductive metal includes a first switching end and a second switching end, and the first switching end and the second switching end reciprocally displace And switching between the first magnetic conductive metal and the second magnetic conductive metal; wherein the second switching end is connected to the second magnetic conductive metal when the first switching end is connected to the first magnetic conductive metal. The micro-vibration generator of claim 1, wherein the first magnetic conductive metal comprises a first guiding pin and a second guiding pin, and the second magnetic guiding metal comprises a first contact pin and a first a second contact end, the first switching end is disposed between the first guiding pin and the first contact pin, and the second switching end is disposed between the second guiding pin and the second contact pin, the first guiding The first switching pitch is separated from the first contact pin by a second switching pitch, and the second switching pitch is equal to the second switching pitch. The micro-vibration generator of claim 2, wherein the second switching end is connected to the second contact pin when the first switching end is connected to the first guiding pin. The micro-vibration generator of claim 1, wherein the first magnetic conductive metal, the second magnetic conductive metal and the third magnetic conductive metal have a concave cross section, and the first magnetic conductive metal The second magnetic conductive metal includes a second recess, and the third magnetic conductive metal further includes a third recess, the first recess has the same orientation as the second recess The orientation of the first recess is opposite to the orientation of the third recess. The micro-vibration generator according to claim 1, wherein the micro-vibration generator further comprises: a conductive metal wire, surrounding the third magnetic conductive metal to form a plurality of turns a columnar body; and a voltage stabilizing circuit connecting the conductive metal wire, the conductive metal wire providing a current to the voltage stabilizing circuit, the voltage stabilizing circuit providing a voltage to the electronic component. A micro-vibration generator comprising: a magnetic member comprising a first magnetic pole and a second magnetic pole; a first magnetic conductive metal connecting the first magnetic pole; and a second magnetic conductive metal connecting the second magnetic pole, The second magnetic conductive metal is spaced apart from the first magnetic conductive metal; and a third magnetic conductive metal includes a first switching end and a second switching end, and the first switching end and the second switching end reciprocally displace Switching between the first magnetic conductive metal and the second magnetic conductive metal; When the first switching end is connected to the second magnetic conductive metal, the second switching end is connected to the first magnetic conductive metal. The micro-vibration generator of claim 6, wherein the first magnetic conductive metal comprises a first guiding pin and a second guiding pin, and the second magnetic guiding metal comprises a first contact pin and a first a second contact end, the first switching end is disposed between the first guiding pin and the first contact pin, and the second switching end is disposed between the second guiding pin and the second contact pin, the first guiding The first switching pitch is separated from the first contact pin by a second switching pitch, and the second switching pitch is equal to the second switching pitch. The micro-vibration generator of claim 7, wherein the second switching end is connected to the second guiding pin when the first switching end is connected to the first contact pin. The micro-vibration generator of claim 6, wherein the first magnetic conductive metal, the second magnetic conductive metal and the third magnetic conductive metal have a concave cross-section, the first magnetic conductive metal The second magnetic conductive metal includes a second recess, and the third magnetic conductive metal further includes a third recess, the first recess has the same orientation as the second recess The orientation of the first recess is opposite to the orientation of the third recess. The micro-vibration generator of claim 6, wherein the micro-vibration generator further comprises: a conductive metal wire, surrounding the third magnetic conductive metal to form a plurality of turns a columnar body; and a voltage stabilizing circuit connecting the conductive metal wire, the conductive metal wire providing a current to the voltage stabilizing circuit, the voltage stabilizing circuit providing a voltage to the electronic component. A method for controlling a micro-vibration generator according to claim 1, comprising the following steps: a first manipulation step of setting the first magnetic conductive metal and the second magnetic conductive metal to be the same a switching pitch and a second switching pitch, and the first switching end and the second switching end of the third magnetic conductive metal are respectively disposed in the first switching pitch and the second switching pitch; and a first The second control step is to position the third magnetic conductive metal between the first magnetic conductive metal and the second magnetic conductive metal, and control the first switching end and the second switching end to be detachably connected to the The first magnetic conductive metal and the second magnetic conductive metal cause the magnetic pole of the first switching end to alternately switch with the magnetic pole of the second switching end. The control method of the micro-vibration generator as described in claim 11 of the patent scope further includes: In a third control step, a plurality of turns of the columnar body are formed by wrapping a conductive metal wire around the third magnetic conductive metal, and the conductive metal wire is wrapped around the intermediate portion of the third magnetic conductive metal. The method for controlling a micro-vibration generator according to claim 11 is for supplying power to an electronic component, and the method for controlling the micro-vibration generator further comprises: a fourth control step, which is provided through a conductive metal wire A current to a voltage stabilizing circuit causes the voltage stabilizing circuit to provide a voltage to the electronic component.