TWM512851U - Acoustic wireless charging device - Google Patents

Description

Acoustic wireless charging device

The present invention relates to a sonic wireless charging device, and more particularly to a sonic wireless charging device that generates an acoustic wave by vibration and generates a current by transmitting a sound wave through a medium.

With the advancement of the times, technology products are becoming more and more crappy, and the manufacture and use of mobile phones, tablets, and computers are constantly changing, but the charging technology does not seem to change much. Basically, they are all powered by a power cord. The device and the device being charged, the use of the power cord not only makes the user feel inconvenience, but also limits the development of the product. In order to change the inconvenience and limitations of charging methods, related manufacturers have begun to deploy new power supply technologies in recent years, and "wireless charging" is a high-profile development focus. If the wireless charging technology is mature, smart phones, watches, bracelets, glasses, etc. will be completely sealed to achieve waterproof and dustproof effects. Wireless charging has several advantages:

(1) Safety: No power contact design can avoid the danger of electric shock.

(2) Durable: The power transmission component is not exposed, so it will not be eroded by moisture, oxygen, etc. in the air, and there is no contact, so it will not be caused by mechanical wear and flashover during connection and separation. loss.

(3) Convenient: no need to connect with wires when charging, just put it near the wireless charger to charge. Technically, a wireless charger can charge a plurality of powered devices. In the case where multiple powered devices need to be charged, multiple wired chargers are not required, no multiple power outlets are required, and no multiple wires are used. The problem of entanglement.

Wireless charging, also known as inductive charging or non-contact inductive charging, utilizes near-field sensing, that is, inductive coupling, by which a power supply device (wireless charger) transfers energy to a powered device that uses the received device. Energy charges the battery, or both. Since the wireless charger and the electric device transmit energy by inductive coupling, the wires are not connected between the two, so the charger and the electric device can be exposed without conductive contacts, so it is more convenient to use than wired charging. .

The principle of wireless charging is the application of electromagnetic induction. Generally, a coil is arranged in a wireless charging charger, and an alternating electromagnetic field is generated by an alternating current, and another alternating coil is disposed in the electric device to receive the alternating electromagnetic field and converted into electric energy, and the received electric energy is in the device. The battery is charged or the device is used for power usage. The situation is equivalent to placing the primary and secondary coils of the transformer into the wireless charger and the consumer.

As can be seen from the above description, in the prior art, the charging technology used for wireless charging is mainly electromagnetic induction, that is, an alternating current electromagnetic field is generated by using one coil through an alternating current, and the alternating electromagnetic field is received at another coil and converted into electric energy. . The prior art does not disclose a wireless charging technique that uses sound waves to generate resonance through a medium and convert sound waves into electrical energy. Therefore, a wireless charging technology that uses sound waves to generate resonance and convert into electrical energy through the medium should be urgently developed and equipped in the field. Creative creation.

Based on the above statement, the main object of the present invention is to provide an acoustic wireless charging device, which comprises: an acoustic wave generating unit for generating sound waves; a sound wave generating unit for generating electrical energy through sound waves; and a storage unit; Used to store electrical energy. The sound wave generating unit further includes a power source, a first coil, a first magnet and a first vibrating film. The power source is configured to provide power, the first coil is electrically coupled to the power source, and when the current of the power source is passed into the first coil, electromagnetic is generated, and the first magnet is disposed in the first coil. When a coil generates electromagnetic force, the first magnet is vibrated by electromagnetic force to vibrate, and the first vibrating film vibrates in accordance with vibration of the first magnet to generate sound waves. The sonic power generation unit further includes a second vibrating membrane, a second magnet, and a second coil. The second vibrating membrane is configured to receive a sound wave transmitted by a medium and generate vibration, and the second magnet is disposed in the second coil and can vibrate according to the vibration of the second vibrating film, when the second When the magnet vibrates, the second coil generates electric energy due to electromagnetic induction, and the electric energy is stored in the electric storage unit for use when needed.

Please refer to FIG. 1 , which is a schematic diagram of the structure of the acoustic wave wireless charging device of the present invention. It can be seen from FIG. 1 that the acoustic wave wireless charging device 01 of the present invention comprises: a sound wave generating unit 011 for generating sound waves; a sound wave power generating unit 012 for generating electric energy through the sound waves; and a power storage unit 013 for storing electric energy. The sound wave generating unit 011 further includes a power source 0111, a first coil 0112, a first magnet 0113, and a first vibration film 0114. The power source 0111 is used to provide power. The first coil 0112 is electrically coupled to the power source 0111. When the current of the power source 0111 passes into the first coil 0112, electromagnetic force is generated. The first magnet 0113 is disposed on the first coil. In the case of 0112, when the first coil 0112 generates electromagnetic force, the first magnet 0113 is vibrated by electromagnetic force, and the first vibrating film 0114 vibrates with the vibration of the first magnet 0113 to generate the acoustic wave 014. The sonic power generation unit 012 further includes a second vibrating film 0121, a second magnet 0122, and a second coil 0123. The second vibrating film 0121 is configured to receive a sound wave 014 transmitted by a medium 015 and generate vibration. The second magnet 0122 is disposed in the second coil 0123, and may vibrate along with the second vibrating film 0121. When the second magnet 0122 vibrates, the second coil 0123 generates electric energy due to electromagnetic induction, and the electric energy is stored in the electric storage unit 013 for use when needed.

Please refer to FIG. 2. FIG. 2 is a schematic structural diagram of an embodiment of the acoustic wave wireless charging device of the present invention. Fig. 2 is a view showing the state in which the acoustic wave wireless charging device of the present invention is used in the air. As shown in FIG. 2, the acoustic wave wireless charging device 02 of the present invention comprises: a sound wave generating unit 021 for generating sound waves; a sound wave power generating unit 022 for generating electric energy through sound waves; and a power storage unit 023 for storing electric energy. The sound wave generating unit 021 further includes a power source 0211, a first coil 0212, a first magnet 0213, and a first vibration film 0214. The vibration film 0214 can be made of corrugated paper. The power source 0211 is used to provide power. The first coil 0212 is electrically connected to the power source 0211. When the current of the power source 0211 is passed into the first coil 0212, electromagnetic force is generated. The first magnet 0213 is disposed on the first coil. In 0212, when the first coil 0212 generates electromagnetic force, the first magnet 0213 is vibrated by the electromagnetic force to generate vibration, and the first vibrating film 0214 vibrates according to the vibration of the first magnet 0213 to generate the acoustic wave 024. The sonic power generation unit 012 further includes a second vibrating film 0221, a second magnet 0022, and a second coil 0223. In this embodiment, the second vibrating film 0221 can be made of corrugated paper for receiving a sound wave 024 transmitted by a medium 025 and generating vibration. In this embodiment, the medium 025 can be air. The second magnet 0222 is disposed in the second coil 0223 and can vibrate according to the vibration of the second vibrating film 0221 (corrugated paper). When the second magnet 0222 vibrates, the second magnet is vibrated. The coil 0223 generates electrical energy, which is stored in the storage unit 023 for use when needed.

Please refer to FIG. 3. FIG. 3 is a schematic structural diagram of another embodiment of the acoustic wave wireless charging device of the present invention. As can be seen from FIG. 3, the acoustic wave wireless charging device 03 of the present invention comprises: a sound wave generating unit 031 for generating sound waves; a sound wave power generating unit 032 for generating electric energy through sound waves; and a power storage unit 033 for storing electric energy. The sound wave generating unit 031 further includes a power source 0311, a first coil 0312, a first magnet 0313, and a first vibration film 0314. The power source 0311 is configured to provide power. The first coil 0312 is electrically coupled to the power source 0311. When the current of the power source 0311 passes into the first coil 0312, electromagnetic force is generated. The first magnet 0313 is disposed on the first coil. In the case of 0312, when the first coil 0312 generates electromagnetic force, the first magnet 0313 is vibrated by the electromagnetic force to generate vibration, and the first vibrating film 0314 vibrates in accordance with the vibration of the first magnet 0313 to generate the acoustic wave 034. The sonic power generation unit 032 further includes a second vibrating film 0221, a second magnet 0322, a second coil 0323, and a waterproof module 0324. The second vibrating film 0221 is configured to receive the sound wave 034 transmitted by the medium 035 and generate vibration. The second magnet 032 is disposed in the second coil 0323, and the vibration of the second vibrating film 0221 may be Vibrating, when the second magnet 0322 vibrates, the second coil 0323 generates electric energy due to electromagnetic induction, and the electric energy is stored in the electric storage unit 033 for use when needed. As shown in FIG. 3, in the embodiment, the sonic power generation unit 032 further includes a waterproof module 0324, and the waterproof module 0324 closely covers the sonic power generation unit 032, so that the sonic power generation unit 032 is in a humid environment. The power generation can continue to operate and the power storage unit 033 is continuously charged.

Please refer to FIG. 4, which is a schematic diagram of the acoustic wave wireless charging device of the present invention used in a liquid. As can be seen from FIG. 4, the acoustic wave wireless charging device 04 of the present invention comprises: a sound wave generating unit 041 for generating sound waves; a sound wave power generating unit 042 for generating electric energy through sound waves; and a power storage unit 043 for storing electric energy. The sound wave generating unit 041 further includes a power source 0411, a first coil 0412, a first magnet 0413, and a first vibration film 0414. The first vibration film 0414 can be made of a waterproof material. The power source 0411 is configured to provide power. The first coil 0412 is electrically coupled to the power source 0411. When the current of the power source 0411 is passed into the first coil 0412, electromagnetic force is generated. The first magnet 0413 is disposed on the first coil. In the case of 0412, when the first coil 0412 generates electromagnetic force, the first magnet 0413 is vibrated by the electromagnetic force to generate vibration, and the first vibrating film 0414 vibrates in accordance with the vibration of the first magnet 0413 to generate the acoustic wave 044. The sonic power generation unit 042 further includes a second vibrating film 0421, a second magnet 0422, a second coil 0423, and a waterproof module 0424. In this embodiment, the second vibrating film 0421 can be made of a waterproof material for receiving a sound wave 044 transmitted by a medium 045 and generating vibration. In this embodiment, the medium 045 can be a liquid. The second magnet 0422 is disposed in the second coil 0423 and can vibrate according to the vibration of the second vibrating film 0421 (waterproof material). When the second magnet 0422 vibrates, the second coil 0423 is induced by electromagnetic induction. Electrical energy is generated, which is stored in the power storage unit 043 for use when needed. As shown in FIG. 4, in the embodiment, the sound wave generating unit 041 further includes a waterproof module 0415, and the waterproof module 0415 can tightly coat the sound wave generating unit 041, so that the sound wave generating unit 041 is on the medium 045. It can continue to operate in a liquid environment. Similarly, the sonic power generation unit 042 further includes a waterproof module 0424. The waterproof module 0424 tightly covers the sonic power generation unit 042, so that the sonic power generation unit 042 can continue to operate in the environment where the medium 045 is liquid. And continuously charging the power storage unit 043.

Referring to FIGS. 5A to 5C, FIGS. 5A to 5C are schematic diagrams showing the structure of the vibrating film in the acoustic wireless charging device of the present invention. As can be seen from FIG. 5A, the structure of the vibrating film (e.g., component 0114 or element 0121 in FIG. 1) of the present invention can be a hollow structure, and the structure can be divided into an upper wall 51. A wall portion (not shown) and a plurality of intermediate legs 52 are formed, and a hollow plenum structure 53 is formed between the middle column and the middle column. Referring to FIG. 5B, it can be seen from FIG. 5B that the structure of the vibrating film in the acoustic wireless charging device of the present invention is also a hole-like structure, which is hollow, and the structure can be divided into an upper wall surface 54 and a lower wall surface (not shown). The plurality of intermediate legs 55 are three-part, which differs from the 5A in that a plurality of intermediate legs 55 are undulating in geometry, and a hollow plenum structure 56 is also formed between the intermediate legs and the intermediate legs. Referring to FIG. 5C, it can be seen from FIG. 5C that the structure of the vibrating film in the acoustic wireless charging device of the present invention is also a hole-like structure, which is hollow, and the structure can be divided into an upper wall surface 57 and a lower wall surface (not shown). A plurality of intermediate legs 58 are three-part, which differ from 5A and 5B in that a plurality of intermediate legs 58 are in a triangular geometry, and a hollow plenum structure 59 is also formed between the intermediate legs and the intermediate legs.

As described in the above description of the embodiments, the sonic wireless charging device provided by the present invention is quite innovative compared to the prior art. In the prior art, the charging technology used for wireless charging is mainly electromagnetic induction, that is, an alternating current electromagnetic field is generated by using one coil through an alternating current, and the alternating electromagnetic field is received at another coil and converted into electric energy. The sonic wireless charging device provided by this creation uses sound waves, generates resonance through the medium, and converts sound waves into electric energy, which is an innovative creation. The detailed description above is for the specific description of the possible embodiments of the present invention, but the embodiments are not intended to limit the scope of the patents, and the equivalent implementations or modifications that are not included in the spirit of the present invention should be included in The patent scope of this case.

01‧‧‧Sonic wireless charging device
011‧‧‧Sonic generating unit
0111‧‧‧Power supply
0112‧‧‧First coil
0113‧‧‧First magnet
0114‧‧‧First vibrating film
012‧‧‧Sonic power generation unit
0121‧‧‧Second vibrating film
0122‧‧‧Second magnet
0123‧‧‧second coil
013‧‧‧Power storage unit
014‧‧‧Sonic
015‧‧‧Media
02‧‧‧Sonic wireless charging device
021‧‧‧Sonic generating unit
0211‧‧‧Power supply
0212‧‧‧First coil
0213‧‧‧First magnet
0214‧‧‧First vibrating film
022‧‧‧Sonic power generation unit
0221‧‧‧Second vibrating film
0222‧‧‧Second magnet
0223‧‧‧second coil
023‧‧‧Power storage unit
024‧‧‧Sonic
025‧‧‧Media
03‧‧‧Sonic wireless charging device
031‧‧‧Sonic generating unit
0311‧‧‧Power supply
0312‧‧‧First coil
0313‧‧‧First magnet
0314‧‧‧First vibrating film
032‧‧‧Sonic power generation unit
0321‧‧‧Second vibrating film
0322‧‧‧Second magnet
0323‧‧‧second coil
0324‧‧‧Waterproof module
033‧‧‧Power storage unit
034‧‧‧Sonic
035‧‧‧Media
04‧‧‧Sonic wireless charging device
041‧‧‧Sonic generating unit
0411‧‧‧Power supply
0412‧‧‧First coil
0413‧‧‧First magnet
0414‧‧‧First vibrating film
0415‧‧‧Waterproof module
042‧‧‧Sonic power generation unit
0421‧‧‧Second vibrating film
0422‧‧‧Second magnet
0423‧‧‧second coil
0424‧‧‧Waterproof module
043‧‧‧Power storage unit
044‧‧‧Sonic
045‧‧‧Media
051‧‧‧Upper wall
052‧‧‧ middle column foot
053‧‧‧Void chamber structure
054‧‧‧Upper wall
055‧‧‧ middle column foot
056‧‧‧Void chamber structure
057‧‧‧ upper wall
058‧‧‧ middle column foot
059‧‧‧Void chamber structure

Figure 1 is a schematic diagram of the architecture of the sonic wireless charging device. Figure 2 is a schematic diagram of the use of the sonic wireless charging device of the present invention in a gas. FIG. 3 is a schematic structural diagram of another embodiment of the sonic wireless charging device of the present invention. Figure 4 is a schematic diagram of the use of the sonic wireless charging device of the present invention in a liquid. 5A to 5C are schematic views showing the structure of a vibrating film in the acoustic wave wireless charging device of the present invention.

01‧‧‧Sonic wireless charging device

011‧‧‧Sonic generating unit

0111‧‧‧Power supply

0112‧‧‧First coil

0113‧‧‧First magnet

0114‧‧‧First vibrating film

012‧‧‧Sonic power generation unit

0121‧‧‧Second vibrating film

0122‧‧‧Second magnet

0123‧‧‧second coil

013‧‧‧Power storage unit

014‧‧‧Sonic

015‧‧‧Media

Claims (11)

An acoustic wave wireless charging device, comprising: a sound wave generating unit for generating sound waves; a sound wave power generating unit for generating electric energy through sound waves; and an electric storage unit for storing electric energy; wherein the sound wave generating unit further comprises a a power source, a first coil, a first magnet, and a first vibrating membrane, the power source is configured to supply a current, the first coil is electrically connected to the power source, and the current is generated when the current of the power source is passed into the first coil Electromagnetically, the first magnet is disposed in the first coil. When the first coil generates electromagnetic force, the first magnet is vibrated by the electromagnetic force to generate vibration, and the first vibrating membrane vibrates according to the vibration of the first magnet. Generating an acoustic wave; the sonic power generating unit further includes a second vibrating film, a second magnet and a second coil, wherein the second vibrating film is configured to receive a sound transmitted by the medium and generate vibration, the second magnet Provided in the second coil, which can vibrate according to the vibration of the second vibrating membrane. When the second magnet vibrates, the second coil generates electric energy due to electromagnetic induction. This electrical energy is stored in the electricity storage unit within. The sonic wireless charging device of claim 1, wherein the first vibrating membrane or the second vibrating membrane is corrugated. The sonic wireless charging device of claim 1, wherein the first vibrating film or the second vibrating film is a waterproof material film. The sonic wireless charging device of claim 1, wherein the medium is a gas. The acoustic wave wireless charging device of claim 1, wherein the sound wave generating unit further comprises a waterproof module, the waterproof module tightly covering the sound wave generating unit, so that the sound wave generating unit can be used in a liquid. The sonic wireless charging device of claim 1, wherein the sonic power generating unit further comprises a waterproof module, the waterproof module closely covering the sonic generating unit, so that the sonic generating unit can be used in a liquid. The sonic wireless charging device of claim 5, wherein the medium is a liquid. The sonic wireless charging device of claim 6, wherein the medium is a liquid. The acoustic wave wireless charging device of claim 1, wherein the first vibrating membrane or the second vibrating membrane is in a hollow structure, and the structure may include an upper wall surface, a lower wall surface and a plurality of intermediate columns. a foot, and a hollow plenum structure is formed between the middle leg and the middle leg. The acoustic wave wireless charging device of claim 1, wherein the first vibrating membrane or the second vibrating membrane is in a hollow structure, and the structure may include an upper wall surface, a lower wall surface and a plurality of intermediate columns. The foot, the middle leg has a wave geometry, and a hollow cavity structure is formed between the middle leg and the middle leg. The acoustic wave wireless charging device of claim 1, wherein the first vibrating membrane or the second vibrating membrane is in a hollow structure, and the structure may include an upper wall surface, a lower wall surface and a plurality of intermediate columns. The foot has a triangular geometry and a hollow plenum structure is formed between the intermediate leg and the intermediate leg.