KR101198072B1 - Wireless battery charging method and device using vibration of magnetelastic material - Google Patents

Abstract

The method of wirelessly charging the rechargeable battery in the target equipment includes disposing a magnetic elastic body and a coil connected to the rechargeable battery in the magnetic field, having a magnetic elastic body using a magnetic field, and using a magnetic elastic body in the coil. Generating a current, and charging the rechargeable battery using the generated current.

Description

Wireless charging method and charging device using the excitation of the magnetic elastomer {WIRELESS BATTERY CHARGING METHOD AND DEVICE USING VIBRATION OF MAGNETELASTIC MATERIAL}

The present invention relates to wireless or contactless charging, and more particularly, to a wireless charging method and apparatus capable of safely performing wireless or contactless charging in an environment where high frequency charging is difficult such as a human body.

Conventional wireless or contactless wireless charging methods include induction coupling charging and non-radioactive charging.

Induction coupling charging is a method in which coils having high frequency alternating current are disposed adjacent to each other, and energy is transferred from a coil connected to a power source to a coil connected to a rechargeable battery using an induction phenomenon of alternating current. In this regard, it is mentioned in detail in Korean Patent Registration No. 10-853889, Korean Patent Registration No. 10-896104, and the like.

However, this induction coupling charging method has high transmission efficiency because it is formed at adjacent distances, and the stability of the technology is recognized in the commercialization stage. However, the disadvantages are that the application distance is short and sensitive to the direction in which the coil is placed. It may be pointed out.

In this regard, the non-radiative wireless charging method uses a non-radiative field as a medium for energy transmission, and is designed to resonate in the field using a coil. It features. This resonance can increase mutual induction between the two coils, can be applied at a far distance than the above-described charging method of the flow, and there is an advantage that energy is transmitted only to the device having the same resonance frequency. However, this also has a disadvantage that the coil is difficult to practical use because a coil of about 50cm in diameter should be used.

Wireless charging can be used in many fields. For example, devices have been developed to be inserted into the human body to perform specific functions or to measure changes in physical conditions, in which wireless charging is essential. However, as in the related art, the induction method using a high frequency current may have a bad effect on the human body at the same time as charging, and may also functionally collide with other devices. In addition, since more than 70% of the human body is made of water, the charging of the induction method using a high frequency current may suddenly decrease the efficiency.

The present invention does not form an electromagnetic field using high frequency, and provides a wireless charging method and apparatus that can prevent mutual side effects that may occur with the human body as well as other peripheral devices.

The present invention provides a wireless charging method and apparatus that can relatively increase the application distance.

The present invention provides a wireless charging method and apparatus that can be manufactured in a small size can form a small size of the target equipment equipped with a rechargeable battery, and can be made small enough to be inserted into a human body.

According to one exemplary embodiment of the present invention, a method of wirelessly charging a rechargeable battery in an object device includes disposing a magnetic elastic body and a coil connected to the rechargeable battery around the magnetic elastic body in a magnetic field, having the magnetic elastic body using the magnetic field. The method may include generating a current in a coil using excitation of a magnetic elastic body, and charging the rechargeable battery using the generated current.

The filling method according to the present embodiment uses a magnetelastic material, which is also called a magnetostrictive material, and may mean a material using magnetostrictive phenomenon. The magnetostrictive phenomenon is a shape that is distorted by magnetism. When magnetized by high frequency alternating current, elasticity is repeated, and the high frequency alternating electric field maintains repetitive vibrations on rods, thin films, etc. made of the material, and the vibration occurs. If the frequency of this vibration coincides with the natural frequency of the magnetostrictive material object, a large value of amplitude can occur. Magnetoelastic or magnetostrictive materials can be used in many applications, including magnetostrictive resonators, magnetostrictive oscillation circuits, and magnetostriction strain gauges that measure pressure and load. Currently used magnetostrictive materials include nickel, iron and cobalt alloys, iron and aluminum alloys, and zinc ferrite.

The magnetic elastic body may be excited according to the change of the magnetic field in the magnetic field, and if the resonance frequency of the magnetic elastic body is matched, an optimal current may be generated through the coil. Because the magnetic field is used, the wireless charging method according to the present embodiment can perform the wireless charging at a far distance than the inductive charging method, and because the change in the magnetic field is used, the energy transfer efficiency is improved even when there is an obstacle occupied by most of the water such as the human body. It can increase. In addition, since it is possible to protect the patient or people around from the adverse effects of high frequency, it can be easily used for medical equipment. First of all, since the coil can be made smaller than the non-radiative wireless charging method, the target equipment can be miniaturized.

Here, the target equipment, as the equipment for maintaining the operating state through charging, may include all the equipment capable of remote charging. For example, it may be a medical device inserted into the human body, and applications such as mobile phones, laptops, and other sensors for non-contact charging may vary.

The magnetoelastic material is provided in a structure capable of vibrating in the target equipment. For example, it can be provided in the form of cantilever, in addition to the both ends are fixed and may also be provided in a structure capable of vibrating in the center.

According to another exemplary embodiment of the present invention, an apparatus for wirelessly charging in a magnetic field includes a charging module, a charging module and a charging module including a base, a possibly mounted magnetic elastic body having a base on the base, and a coil provided around the magnetic elastic body. And a rechargeable battery for charging electrical energy transferred from the charging module unit, wherein the magnetic elastic body is excited in the magnetic field and generates current in the coil by using resonance between the excited magnetic elastic body and the coil. Can be.

The wireless charging method and apparatus of the present invention do not form an electromagnetic field using high frequency to prevent mutual side effects that may occur with the human body as well as other peripheral devices.

Since the wireless charging method and apparatus of the present invention can be applied at a relatively long distance, the wireless charging method and apparatus can be used with high efficiency at a certain proximity. Wireless charging can be easily performed.

Since the wireless charging method and apparatus of the present invention do not require a coil of a large size as in the non-radiative charging method, the target equipment can be manufactured in a small size, and the size of the target equipment equipped with a rechargeable battery can be formed small. In particular, by using a device that can be formed so small in a small device or a device inserted into the human body, the efficiency of wireless charging can be improved.

1 is a view of a charging device according to an embodiment of the present invention.
FIG. 2 is a diagram of a general purpose device using the charging device of FIG. 1.
3 is a view of a charging device according to another embodiment of the present invention.
4 is a view for explaining the internal structure of the charging device of FIG.
5 is a view for explaining an example of use of the target equipment including the charging device of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments. For reference, the same numbers in this description refer to substantially the same elements and can be described with reference to the contents described in the other drawings under these rules, and the contents which are judged to be obvious to the person skilled in the art or repeated can be omitted.

1 is a view of a charging device according to an embodiment of the present invention, Figure 2 is a view of a general purpose device using the charging device of FIG.

1 and 2, the object equipment may include a charging module 100, a charging circuit 210, a rechargeable battery 220, and a functional unit 10. In the target equipment, the functional unit 10 is a module for performing basic functions of the target equipment. When the target equipment is a sensor, the sensing module may be used. In the case of an actuator, the actuator module may be an actuator module. In addition, when the target equipment is a mobile phone, the functional unit may be a device for performing the function of the mobile phone except the power supply unit in the mobile phone.

The charging device 200 includes a charging module 100, a charging circuit 210, and a rechargeable battery 220, and the charging module 100 includes a base 110, a magnetic elastic body 120, and a coil 130. . Specifically, the magnetic elastic body 120 on the base 110 in the magnetic field and the excitation movement, the current may be generated in the coil 130 by the excitation movement of the magnetic elastic body 120.

The current generated by the charging module 100 may be rectified or DC changed through the charging circuit 210 as an alternating current, and the generated electrical energy may be stored in the rechargeable battery 220. Power may be directly supplied to the functional unit 10 through the charging circuit 210 in the target equipment.

The functional unit 10 may sense a phenomenon or conditions occurring in the charging device 200, and detect a charging progress state or change in the charging device 200 and report it to an external device. The setting may be changed in an external magnetic field generating device through mutual reporting using the wireless transmission / reception module 20. The parameter may be adjusted so that the magnetic elastic body 120 and the coil 130 resonate in an optimal state through the setting change. Fine control is possible.

The magnetic elastic body 120 may include a material that is easy to magnetize, and for this purpose, materials such as nickel, iron and cobalt alloys, iron and aluminum alloys, and zinc ferrite may be used. The magnetic elastic body 120 may be excited according to the change of the magnetic field in the magnetic field F. At this time, the optimum current may be generated through the coil if it matches the resonance frequency of the magnetic elastic body. For the excitation movement in the target equipment, the magnetic elastic body 120 may be fixed to the base 110 in the form of a cantilever, otherwise fixed to the base 110 in a state capable of vibrating movement other than the cantilever form Or may be combined.

Since the wireless charging method according to the present embodiment uses a magnetic field, wireless charging can be performed at a longer distance than inductive charging, and since the change in the magnetic field is used, energy transmission efficiency is improved even when there are obstacles occupied by most of the water such as the human body. It can increase. In addition, since it is possible to protect the patient or people around from the adverse effects of high frequency, it can be easily used for medical equipment. In addition, since the coil can be made smaller than the non radiative wireless charging method, the target equipment can be miniaturized.

3 is a view showing a charging device according to another embodiment of the present invention, Figure 4 is a view for explaining the internal structure of the charging device of Figure 3, Figure 5 is a use case of the target equipment including the charging device of FIG. A diagram for explaining.

3 and 4, the charging module 300 includes a base 310, a metal substrate 315, a magnetic elastic body 320, a coil hub 335, and a coil 330. In detail, a metal substrate 315 made of copper is provided in a cantilever shape on one side of the base 310 in the magnetic field, and a thin magnetic elastic body 320 is bonded to the surface of the metal substrate 315. The magnetic elastic body 320 may have a movement on the metal substrate 315 having a cantilever shape, and as shown, the magnetic elastic body 320 may have a movement that is integral with other physical structures.

A coil hub 335 formed of an insulating material is provided around the metal substrate 315 and the magnetic elastic body 320, and the coil 330 is wound around the coil hub 335. In a state in which the coil hub 335 is located, vibration movement of the magnetic elastic body 320 may occur due to a magnetic field change. In addition, a current may be generated in the coil 330 by the relative movement of the magnetic elastic body 320.

The current generated by the charging module 300 may be rectified or DC changed through a charging circuit as an alternating current, and the generated electrical energy may be stored in the rechargeable battery.

The magnetic elastic body 320 may be used as an amorphous alloy ribbon (metglas), and the copper substrate 315 may be bonded to the movement with the substrate.

As shown in FIG. 5, the target equipment including the charging module 300 according to the present embodiment may be located between the Helmholtz coils 30. Helmholtz coils 30 are two identical circular magnetic coils, which may be provided symmetrically on both sides of an area that may contain the desired equipment. The Helmholtz coil 30 may be arranged to be spaced apart by the same distance as the radius of the coil. Between and around the center of the two coils 30 can form a nearly uniform magnetic field distribution, the Helmholtz coil 30, the target equipment can perform a good degree of charging even if there is a slight distortion or position displacement .

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art various modifications and variations of the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: Charge module 110: Base
120: magnetic elastic body 130: coil
200: charging device 210: charging circuit
220: rechargeable battery

Claims (10)

In the method for wirelessly charging the rechargeable battery in the target equipment,
Disposing a magnetic elastic body and a coil connected to the rechargeable battery around the magnetic elastic body in a magnetic field formed by two opposite Helmholtz coils;
Exciting the magnetic elastic body by using a magnetic field formed by the Helmholtz coil:
Generating a current in the coil using the excitation of the magnetic elastomer; And
Charging the rechargeable battery using the generated current;
Wireless charging characterized in that the magnetic field is formed between the Helmholtz coils without forming an electromagnetic field using high frequency, and generates a current in the coil by using the resonance between the excited magnetic elastic body and the coil. Way. The method of claim 1,
The magnetic elastic body is a wireless charging method characterized in that it is provided in a state capable of having a portion fixed in the target equipment. The method of claim 2,
The magnetic elastic body is a wireless charging method, characterized in that provided in the cantilever form in the target equipment. The method of claim 2,
And the magnetoelastic material is laminated on a metal substrate fixed in a form possible with the target equipment. The method of claim 1,
The magnetic elastic body is a wireless charging method, characterized in that provided using at least one of nickel, iron and cobalt alloys, iron and aluminum alloys, zinc ferrite. delete In a device for wireless charging in a magnetic field formed by two opposite Helmholtz coils,
A charging module comprising a base, a magnetoelastic body mounted on the base, and a coil provided around the magnetoelastic body;
A charging circuit unit electrically connected to the charging module; And
It includes; a rechargeable battery for charging the electrical energy transferred from the charging module unit,
The magnetic elastic body is excited in a magnetic field formed between the Helmholtz coils without forming an electromagnetic field using high frequency, and generates a current in the coil by using the resonance between the excited magnetic elastic body and the coil. Charging device. The method of claim 7, wherein
The magnetic elastic body is a wireless charging device, characterized in that provided in the base cantilevered form. The method of claim 7, wherein
And the magnetoelastic material is laminated on a metal substrate fixed in a possible form with the base. The method of claim 7, wherein
The magnetic elastic body is provided using at least one of nickel, iron and cobalt alloys, iron and aluminum alloys, zinc ferrite.

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