TWM499009U - Sonic wave power generating system for organism - Google Patents

Abstract

The present invention is related to a sonic wave power generating system for organism comprising a power generating module and a sonic wave generating module. The power generating module is implanted into an organism body, is resonance and vibrating with a specific sonic wave, and transforms the vibration thereof as electrical power. The sonic wave generating module generates the specific sonic wave having a suitable wavelength to cause the resonance and vibration to the power generating module. The power generating module is able to provide electrical power to an electrical organ inside the organism thus to extend the use period of the electrical organ.

Description

In vivo sonic power generation system

The present invention is a power generation system, and more particularly to a power generation system suitable for implantation in a living body and capable of charging through sound waves.

Technology is changing with each passing day, for research or medical applications. Taking medical applications as an example, in order to replace organs that are disabled due to disease, it is very common to implant permanent or temporary artificial organs. At present, electronic devices commonly implanted in the human body such as an electronic heart, a drug injector, a heart rate adjuster, and the like are left in the living body for a long time according to different needs and working characteristics.

However, all current electronic devices implanted in the body use a primary battery to provide power. When the battery is exhausted, the electronic device must be removed by surgery to replace the new product, so that the organism or human must bear more life threats. Risk, use is extremely constant and not human.

In order to solve the technical problem that the embedded electronic device uses a primary battery and can only be removed by surgery, replaces the new product, and thus causes harm to the life of the living body, the novel sonic power generation technology solves many shortcomings of the prior art. To achieve the technical effect of significantly reducing the life threats and risks to living organisms.

The present invention provides an in vivo sonic power generation system comprising:

An in vivo sonic power generation module, the in vivo sonic power generation module is implanted in a living body, which comprises a sound wave induction power generation unit, a rectification voltage regulation circuit, a rechargeable battery, a power output interface and a biological phase The acoustic induction generating unit generates vibration for a specific wavelength acoustic wave and converts the vibration into electrical energy and outputs the same to the rectifying and stabilizing circuit, and the rectifying and stabilizing circuit regulates and rectifies the electric energy and outputs the electric energy to the rechargeable battery to store the electric power. The power output interface is connected to an electronic component used in the living body, and the power output interface converts the power of the rechargeable battery to an electronic component used in the living body;

An extracorporeal sound wave generating module generates the specific wavelength sound wave, so that the sonic wave power generation module in the living body senses and generates resonance, and then converts the vibration into electric energy and stores it.

The acoustic wave induction power generation unit comprises a magnetic material, an acoustic wave sensing unit and a coil, and the magnetic material is fixedly connected to the acoustic wave sensing unit, and the acoustic wave sensing unit generates a resonance motion of the specific wavelength sound wave and drives the magnetic material to move; The coil is sleeved outside the magnetic material, and generates an induced current when the magnetic material moves; the rectifying and stabilizing circuit rectifies and regulates the induced current and outputs the same to the rechargeable battery for charging.

The external acoustic wave generating module includes a sound signal generator connected in series, an audio adjusting circuit, a sound signal amplifier and a sound wave transmitter, and a power source; the sound signal generator generates an audio signal output to the sound wave signal generator An audio adjustment circuit, the audio adjustment circuit fine-tunes the frequency of the sound wave signal to the specific wavelength sound wave, the sound wave signal amplifier receives the sound wave signal and amplifies the sound wave signal, and the sound wave transmitter receives the amplified sound wave electrical signal and converts The sound wave signal is input to the specific wavelength sound wave, and the power source is respectively connected to the sound wave signal generator, the audio adjusting circuit, the sound wave signal amplifier and the sound wave transmitter, and supplies power.

The electronic component used in the living body includes an integrated thermometer, a regulator, a blood glucose sensor or an artificial heart.

Wherein, the biocompatible outer sleeve is a soft material that is non-toxic to the living organism, bio-tissue compatible or non-rejecting biological tissue.

Wherein, the biocompatible outer sleeve comprises silicone or polylactic acid.

Wherein, the acoustic induction power generation unit is coated on a hard sealing material and then placed in the biocompatible outer casing.

Wherein, a biocompatible fluid is injected into the sealing material.

Wherein, the biocompatible fluid is a physiological saline solution.

In this way, the present invention can generate electricity in a living body for charging or normal operation of other power modules; thus, for research or medical purposes, the organism can be operated without the need for frequent reoperation to maintain the performance of the power module. Therefore, the present invention solves the problems of the prior art and achieves the technical effect of greatly reducing the risk of life safety of the organism.

Please refer to the first figure and the second figure, which is a preferred embodiment of the novel in vivo sonic power generation system, which comprises an in vivo sonic power generation module 10 and an extracorporeal sound wave generating module 20, the in vivo sonic wave generating mode The group 10 is implanted in a living body 50, which comprises a sonic induction generating unit 11, a rectifying and stabilizing circuit 13, a rechargeable battery 15, a power output interface 17, and a biocompatible outer casing 19. The type of the organism 50 is not limited and may be a human or any animal. The so-called proper position refers to a site implanted in the living body 50 without causing serious damage or rejection to the living body 50, for example, implanting the living body 50. The fat layer and other parts can be positioned such as the arm, abdomen, chest, back, etc. of the limbs or the fat layer of the limb.

Referring to FIG. 3A, FIG. 4 and FIG. 4, the acoustic wave induction power generation unit 11 includes a plurality of magnetic materials 111, an acoustic wave sensing unit 114, and a plurality of coils 116. The magnetic material 111 is fixedly connected to the acoustic wave sensing unit 114. The sensing unit 114 is a component that can generate a resonant motion for a specific wavelength of sound waves, for example, a thin film component made of a material that can resonate with ultrasonic waves. When the acoustic wave sensing unit 114 senses the sound wave of the specific wavelength, it drives a plurality of The magnetic material 111 moves along the vibration direction of the acoustic wave sensing unit 114; each of the coils 116 is sleeved on an outer surface of the magnetic material 111, and generates a induced current when the magnetic material 111 moves. .

The rectifying and stabilizing circuit 13 is electrically connected to each of the coils 116, and receives the induced current and rectifies and regulates the voltage. The rechargeable battery 15 is electrically connected to the rectifying and regulating circuit 13 , and receives the rectified and regulated induced current from the rectifying and regulating circuit 13 for charging and storing. The power output interface 17 is electrically connected to the rechargeable battery 15 , and the power output interface 17 is electrically connected to an electronic component 30 used in the living body, and cooperates with the power required for the electronic component 30 used in the living body to operate. The rechargeable battery 15 is adaptively converted into electric power and output to the electronic component 30 used in the living body, so that the electronic component 30 used in the living body can be continuously operated without replacement, thereby solving the problem that the prior art damages the living body 50 by replacing the electronic component. . The electronic components 30 used in the living body may vary depending on the needs, for example, a thermometer, a (heart rhythm) adjuster, a blood glucose sensor, an artificial heart, and the like.

The biocompatible outer casing 19 is a soft material that is non-toxic to the living organism, bio-tissue-compatible or non-repulsive to the biological tissue, such as silicone rubber, polylactic acid (PLA), etc., which coats the acoustic wave induction power generation unit 11, and the rectification is stable. The voltage circuit 13, the rechargeable battery 15 and the power output interface 17 are implanted into the living body 50 without repulsion or influence on the living body 50. In order to allow the bio-inductive casing 19 to cover the acoustic induction power generation unit 11 without affecting the movable mechanism of the acoustic induction power generation unit 11, the acoustic induction power generation unit 11 may be first sealed with a hard sealing material and then placed. In the biocompatible outer casing 19, the acoustic wave induction power generation unit 11 can maintain a freely movable state after being coated on the biocompatible outer casing, and in addition, a biocompatible fluid (for example, physiological saline solution) can be injected during coating. Etc.) In the sealing material, the organism is harmed by avoiding air leakage inside the covering material.

Referring to the first and fifth figures, in order to charge the in vivo sonic power generation module 10, the extracorporeal sound wave generating module 20 includes a series of acoustic wave signal generator 21, an audio adjusting circuit 22, and an acoustic wave. a signal amplifier 23 and an acoustic wave transmitter 24, and a power source 25; the sound wave signal generator 21 generates an acoustic wave signal output to the audio adjusting circuit 22, and the audio adjusting circuit 22 fine-tunes the sound wave electrical signal to the specific wavelength sound wave The frequency adjustment circuit 22 can be a frequency multiplication or frequency adjustment circuit. The sound wave signal amplifier 23 receives and amplifies the sound wave signal that completes the frequency adjustment, and the sound wave transmitter 24 receives the amplified sound wave electrical signal, and converts the sound wave electrical signal into the specific wavelength sound wave and outputs it. The power source 25 is connected to the sound signal generator 21, the audio adjustment circuit 22, the sound signal amplifier 23, and the sound wave transmitter 24, respectively, and provides power required for its operation. In use, the extracorporeal sound wave generating module 20 corresponds to the position of the in vivo sonic power generation module 10, and the specific wavelength sound wave is sent to the output of the in vivo sonic power generation module 10, wherein the specific wavelength sound wave must be A wavelength band that is not absorbed by the tissue of the living body 50, such as an ultrasonic wave, and therefore, the specific wavelength sound wave penetrates the living body 50 to cause the acoustic wave induction power generation unit 11 to resonate and be converted into an electric power output, thereby achieving the foregoing Power generation efficiency.

As can be seen from the foregoing, the present embodiment can generate electric power in a living body, and provide an electronic device that is also implanted in the living body for charging or normal operation. Thus, for research or medical purposes, the organism can be re-surgery to maintain the performance of the electrical equipment in the body. Therefore, the present embodiment can solve the problems of the prior art and greatly reduce the risk of life safety of the organism.

10‧‧‧In vivo sonic power generation system
11‧‧‧Sonic induction power generation unit
111‧‧‧Magnetic materials
114‧‧‧Sonic induction unit
116‧‧‧ coil
13‧‧‧Rectification regulator circuit
15‧‧‧Rechargeable battery
17‧‧‧Power output interface
19‧‧‧Biocompatible jacket
20‧‧‧In vitro sound wave generating module
21‧‧‧Sound signal generator
22‧‧‧Audio adjustment circuit
23‧‧‧Sound Signal Amplifier
24‧‧‧Sonic transmitter
25‧‧‧Power supply
30‧‧‧Electronic components used in living organisms
50‧‧‧ organisms

The first figure is a block diagram of a system according to a preferred embodiment of the present invention. The second figure is a schematic view of the appearance of the extracorporeal sound wave generating module of the preferred embodiment of the present invention. 3A and B are partial enlarged perspective views of the preferred embodiment of the present invention. Figure 4 is a partially enlarged side elevational view of the preferred embodiment of the present invention. Figure 5 is a schematic view showing the use of the preferred embodiment of the present invention.

10‧‧‧In vivo sonic power generation system

11‧‧‧Sonic induction power generation unit

13‧‧‧Rectification regulator circuit

15‧‧‧Rechargeable battery

17‧‧‧Power output interface

19‧‧‧Biocompatible jacket

20‧‧‧In vitro sound wave generating module

21‧‧‧Sound signal generator

22‧‧‧Audio adjustment circuit

23‧‧‧Sound Signal Amplifier

24‧‧‧Sonic transmitter

25‧‧‧Power supply

30‧‧‧Electronic components used in living organisms

Claims (8)

An in vivo sonic power generation system comprising: an in vivo sonic power generation module, wherein the in vivo sonic power generation module is implanted in a living body, and comprises a sound wave induction power generation unit, a rectification voltage stabilization circuit, and a charging a battery, a power output interface and a biocompatible jacket, the acoustic wave induction unit generates vibration for a specific wavelength of sound waves and converts the vibration into electrical energy and outputs the same to the rectifier voltage stabilizing circuit, and the rectifier voltage regulator circuit regulates the power Rectifying and outputting to the rechargeable battery to store power, the power output interface is connected to an electronic component used in a living body, and the power output interface adaptively converts the power of the rechargeable battery to an electronic component used in the living body; And an extracorporeal sound wave generating module that generates the specific wavelength sound wave, so that the sonic wave power generation module in the living body senses and generates resonance, and then converts the vibration into electric energy and stores it. The in-vivo acoustic power generation system according to claim 1, wherein the acoustic induction power generation unit comprises a magnetic material, an acoustic induction unit and a coil, and the magnetic material is fixedly connected to the acoustic induction unit, and the acoustic induction unit is The specific wavelength acoustic wave generates a resonance motion and drives the magnetic material to move; the coil is sleeved outside the magnetic material, and generates an induced current when the magnetic material moves; the rectifying and regulating circuit rectifies and stabilizes the induced current After that, it is output to the rechargeable battery for charging. The in-vivo acoustic wave generating system according to claim 1 or 2, wherein the extracorporeal sound wave generating module comprises a sound signal generator connected in series, an audio adjusting circuit, an acoustic signal amplifier and an acoustic wave transmitter, and a power signal; the sound signal generator generates an audio signal output to the audio adjustment circuit, the audio adjustment circuit fine-tunes the sound signal to a frequency of the specific wavelength sound wave, and the sound signal amplifier receives the sound signal and amplifies the sound signal Receiving, by the sound wave transmitter, the amplified sound wave signal, converting the sound wave signal into the specific wavelength sound wave and outputting the sound wave signal generator, the sound adjusting circuit, the sound wave signal amplifier and the sound source The sonic transmitter connects and provides power. The in-vivo sonic power generation system according to claim 3, wherein the electronic component used in the living body comprises an integrated thermometer, a regulator, a blood glucose sensor or an artificial heart. The in vivo sonic power generation system according to claim 3, wherein the biocompatible outer casing is a soft material that is non-toxic to the living organism, bio-tissue compatible, or non-rejecting biological tissue. The biocompatible acoustic power generation system according to claim 5, wherein the biocompatible outer casing comprises silicone or polylactic acid. The in-vivo sonic power generation system according to claim 5, wherein the acoustic induction power generation unit is coated with a hard sealing material and then placed in the biocompatible outer casing. An in vivo sonic power generation system according to claim 7, wherein the sealing material is filled with a biocompatible fluid.