TWM598693U - Low-frequency vibration wearable device - Google Patents

Abstract

A low-frequency vibration wearable device, which includes: a lighting unit, a low-frequency vibration unit, and a wearing part. The lighting unit includes a light-emitting element and a first body. The low-frequency vibration unit is electrically connected to the lighting unit. The low-frequency vibration unit includes a second body and a horn , The wearing part is connected to the lighting unit and the low-frequency vibration unit, and the wearing part is arranged on the outer periphery of the lighting unit and the low-frequency vibration unit. The wearing part is worn on the test object, and the light-emitting part emits visible light outwards. The wavelength of the visible light is between Between 380nm and 750nm, visible light irradiates the first sheet and excites the first sheet to irradiate infrared light. The horn emits sound waves. The frequency of the sound waves is between 10Hz and 200Hz. Sound waves and infrared light act simultaneously In the test object; by this, the test object transmits sound waves and infrared light to control the energy balance inside the test object and increase the liquid circulation and fluidity.

Description

Low-frequency vibration wearable device

This creation is about a low-frequency vibration device, especially a low-frequency vibration wearable device that improves Brownian motion.

According to this, in 1826, the British scientist "Brown" observed the movement of particles when using a microscope to observe pollen suspended in water. Later, this molecular motion was called "Brownian motion." It is clinically proven that in the case of early ischemic stroke, the "Brownian motion" of water molecules in brain cells decreases. The reason is that blood perfusion in the center of the lesion is reduced, and the Na+, K+, -ATPase pumps on the brain nerve cell membrane ( The function of the tranporter is weakened, and the Na+ and Ca2+ in the extracellular fluid flow into the cell, causing cytotoxic edema, shrinking the extracellular space of nerve cells and reducing the diffusion rate of water molecules, thus limiting the "Brownian motion" of water molecules.

However, "Brownian motion" is also applied to the activity of surviving tumor cancer cells. It has a complete cell membrane. Water is the most important component of the human body. Since the cell wall in the human body forms a natural barrier, it blocks the "Brownian motion" of water molecules. The water molecules inside are more restricted, the movement of water molecules is smaller, the water molecules outside the cell are less restricted, and the movement of water molecules is greater. Therefore, the denser the cells and the more complete the area, the more obstacles are formed, and the greater the restriction on the movement of water molecules. Because the tumor is an abnormal proliferation of cells in the body, the cell density will be higher than that of normal tissue, blocking the "Brownian motion" of water molecules.

In addition, in 1968, a Canadian scholar "Vienna, Austria" and German literature and research pointed out that the use of light from 450nm wavelength to 1100nm wavelength to perform photochemical action on the mitochondria of blood cells, the use of low-energy lasers is mainly biological stimulation Biostimulation, that is, by giving proper energy to stimulate biological cells and induce or intensify physiological responses, it can activate cells and repair damaged cells and produce a protective film to protect the body from free radicals and middle molecular substances. , And then achieve the effect of anti-aging.

The principle of low energy photon therapy (LEPT) is to use photobiomodulation. After irradiating cells with low-energy visible light, they stimulate the cell’s energy factory, the mitochondria, to produce more More energy, and then prolong the life cycle of cells, to achieve the purpose of treatment. This is the same as plant cells rely on sunlight to produce energy through photosynthesis. Since the energy output of these lights is in milliwatts (milliwatts), there is almost no heat generation in clinical practice, and there is no risk of scars caused by scalds.

On the other hand, the pace of life in modern society is accelerating, the social environment is complex, and people’s life pressures are also increasing, making people’s sleep quality generally poor; at the same time, most elderly people or people with lumbar muscle strain are resting or sleeping due to Pain in the waist or other areas usually makes it difficult to sleep. In addition, sonic medicine is the use of scientific instruments to detect or treat human diseases with energy. The methods and principles vary depending on the form of energy. In the bioelectricity experiment, using electrical characteristics research, it is found that the test object (plants, animals) has an abnormal internal function in response to the current. It is indeed possible to measure the relevant response value by a change in the current value. The electric current stimulates the nerve, and then analyzes the overall change and state of the function of the test object.

However, the speaker devices on the market do not have a structure that provides a combined output sound wave and infrared light wavelength, so as to control the "Brownian motion" of the tiny particles in the object under test or the particles in the fluid. Control the relative limitations of the Brownian motion of the water molecules or particles inside the test object, the problem of energy imbalance, and the problem of abnormal liquid circulation.

Therefore, the creator of this case, after observing the above-mentioned shortcomings, came into being.

The main purpose of this creation is to provide a low-frequency vibration wearable device. Through the setting of the wearable part, the low-frequency vibration wearable device can be worn on the object under test, and can control and increase the Brownian motion inside the object under test. The measured object transmits sound waves and infrared light to control the internal energy balance of the measured object and increase liquid circulation and fluidity.

In order to achieve the above purpose, the low-frequency vibration wearable device provided by this creation includes: a lighting unit, the lighting unit includes a lamp holder, at least one light-emitting element and a first body, the light-emitting element is arranged on the In the lamp holder, the first plate system is connected to the lamp holder and covers the light-emitting element; a low-frequency vibration unit, the low-frequency vibration unit is electrically connected to the lighting unit, and the low-frequency vibration unit includes a second plate and a The horn includes a frame, a magnetic return member and a spring wave, the second sheet system is arranged on the frame, the magnetic return member is arranged on the bottom side of the frame, and the middle position of the magnetic return member is A groove is recessed, a magnetic cylinder and a voice coil are arranged in the middle of the groove, the voice coil is sleeved on the magnetic cylinder with linear displacement, and the middle position of the elastic wave is sleeved The voice coil; and a wearing piece connected to the lighting unit and the low-frequency vibration unit, and with the wearing piece set on the outer periphery of the lighting unit and the low-frequency vibration unit, the wearing piece is worn on On a test object; wherein, the light emitting element emits a visible light outward, the wavelength of the visible light is between 380nm and 750nm, the first sheet body and the second sheet system are selected from bioceramic sheets and plant sheets One of or a combination thereof, the visible light system irradiates the first sheet and excites the first sheet to irradiate an infrared light, and the first sheet and the second sheet system can absorb the visible light In the characteristic of infrared light photons, the horn emits a sound wave, the frequency of the sound wave is between 10 Hz and 200 Hz, and the sound wave and the infrared light system act on the test object at the same time.

Preferably, wherein the wearing part is a watchband, and the wearing part is flexible.

Preferably, the first sheet body and the second sheet system have flexibility, and the first sheet body and the second sheet system have the characteristic of emitting infrared photons in the visible light.

Preferably, wherein the first sheet body and the second sheet system are bioceramic sheets, and the first sheet body and the second sheet body contain a plurality of oxide mineral particles.

Preferably, the wavelength of the infrared photon that the first sheet body absorbs includes mid-infrared light of 2.75 μm to 3.59 μm.

Preferably, wherein the wavelength of the infrared photon that the first sheet body absorbs includes far-infrared light of 6 to 20 microns.

Preferably, the first sheet and the second sheet system are selected from one of a thin sheet, a thick sheet and a film.

Preferably, wherein the first sheet body and the second sheet system are plant sheets.

Preferably, the oxide mineral particles are evenly distributed in the one piece and the second piece.

Preferably, the oxide mineral particles include a plurality of alumina particles.

The low-frequency vibration wearable device provided by this creation is mainly based on the arrangement of the first piece and the second piece, and the arrangement of the wearing part, so that the low-frequency vibration wearable device can be stably worn on the receiving device. On the test object, and the first sheet body and the second sheet system are bioceramic sheets or plant sheets, the visible light excites the first sheet body to irradiate the infrared light, and absorb infrared photons in the visible light The characteristics of the low-frequency vibration wearable device of this creation, when the low-frequency vibration wearable device is in operation, the sound wave and the infrared light output by it can control and or increase the Brownian motion inside the test object; more specifically, by The sound wave and the infrared light are combined and output by the device, so as to achieve the control of the internal energy balance of the test object and increase the liquid circulation and fluidity.

(First embodiment) Hereinafter, with reference to the drawings, the implementation of the first embodiment of the low-frequency vibration wearable device created by this invention will be described.

Please refer to Figures 1 to 4. Figure 1 is a perspective view of the first embodiment of the creation, Figure 2 is a schematic diagram of the first embodiment of the creation, and Figure 3 is an exploded view of the low-frequency vibration unit of the first embodiment of the creation. Figure 4 is an exploded view of the lighting unit of the first embodiment of the creation. This creation department discloses a low-frequency vibration wearable device 100, which includes:

A lighting unit 10, the lighting unit 10 includes a lamp holder 11, at least one light-emitting element 12 and a first plate 13, the light-emitting element 12 is arranged in the lamp holder 11, the first plate 13 and The lamp holder 11 is connected to and covers the light emitting element 12.

A low-frequency vibration unit 20, the low-frequency vibration unit 20 is electrically connected to the lighting unit 10, the low-frequency vibration unit 20 includes a second plate 21 and a horn 22, the horn 22 includes a frame 221, a magnetic return The second sheet body 21 is arranged on the frame 221, the magnetic return member 222 is arranged on the bottom side of the frame 221, and the middle position of the magnetic return member 222 is recessed. A magnetic cylinder 224 and a voice coil 225 are arranged at the middle position of the groove 2221, and the voice coil 225 is sleeved on the magnetic cylinder 224 with linear displacement. The middle position of the elastic wave 223 is Set on the voice coil 225.

A wearing part 30 connected to the lighting unit 10 and the low-frequency vibration unit 20, and with the wearing part 30 set on the outer periphery of the lighting unit 10 and the low-frequency vibration unit 20, the wearing part 30 is It is worn on a test object 200.

Please continue to refer to FIG. 2, the light-emitting element 12 emits a visible light 121 outward, the wavelength of the visible light 121 is between 380nm and 750nm, the first sheet 13 and the second sheet 21 are selected from One or a combination of a bioceramic sheet and a plant sheet, the visible light 121 irradiates the first sheet 13 and excites the first sheet 13 to irradiate an infrared light 131, and the first sheet 13 and the second sheet 21 have the characteristic of absorbing infrared photons in the visible light 121, the horn 22 emits a sound wave 226, the frequency of the sound wave 226 is between 10Hz and 200Hz, the sound wave 226 and The infrared light 131 acts on the object 200 at the same time.

In this embodiment, the first sheet 13 and the second sheet 21 are flexible, and the first sheet 13 and the second sheet 21 are selected from a thin sheet and a thick sheet. One of the first sheet body 13 and the second sheet body 21 is a bioceramic sheet, and the first sheet body 13 and the second sheet body 21 contain a plurality of oxide mineral particles, the oxide mineral The particles are evenly distributed in the one piece 13 and the second piece 21, and the oxide mineral particles include a plurality of alumina particles.

Specifically, the first sheet body 13 and the second sheet body 21 are bioceramic sheets, and 80% to 99.9% of the first sheet body 13 and the second sheet body 21 are the oxide minerals Particles, and the oxide mineral particles contain 60% to 95% of the alumina particles, the first sheet 13 absorbs infrared light photons with a wavelength including mid-infrared light of 2.75 microns to 3.59 microns, and the first sheet 13 The wavelength that absorbs infrared photons includes far-infrared light of 6 to 20 microns. However, this creation is not limited to this. In another preferred implementation, the first sheet 13 and the second sheet 21 are plant sheets.

In order to provide a further understanding of the structural features of this creation, the use of technical means and the expected effects, the method of use of this creation is described. I believe that we can have a deeper and specific understanding of this creation from this, as described below:

In the use state, once again clarify the "Brownian motion", Brownian motion (Brownian motion) is the irregular motion of tiny particles or particles in the fluid. The Brownian motion process is a continuous random process with normally distributed independent increments.

Please refer to Figures 5-9. Figure 5 is a schematic diagram of the use state of the first embodiment of the creation. Figure 6 is the luminescence spectrum and energy distribution diagram of the glass sheet in the first embodiment of the creation. Figure 7 is the creation. The luminescence spectrum and energy distribution diagram of the glass body of the first embodiment, FIG. 8 is the luminescence spectrum and energy distribution diagram of the glass body of the first embodiment of creation, and FIG. 9 is the glass body of the first embodiment of creation The Brownian motion analysis diagram of small molecules in liquid recorded through the laser light clamp experiment. The wearing part 30 is a watchband, and the wearing part 30 is flexible. The wearing piece 30 is worn on the wrist of the test object 200, but this creation is not limited to this. The wearing piece 30 can be worn as a headband, belt, and chain strap, and the wearing position depends on the use The needs of the people have changed.

When in use, this creation is mainly based on the arrangement of the first sheet 13 and the second sheet 21, the visible light 121 illuminates the first sheet 13, and excites the first sheet 13 to illuminate outward The infrared light 131 is emitted, and the first sheet body 13 and the second sheet body 21 have the characteristic of absorbing infrared photons in the visible light 121 and the characteristic of emitting infrared photons in the visible light 121 for When the low-frequency vibration wearable device 100 for this creation is in operation, the sound wave 226 and the infrared light 131 output by it can control and or increase the Brownian motion inside the body of the test object 200.

It should be further explained that different wavelengths represent different light colors and have different effects. Red light, with a wavelength of 639nm, is the longest wavelength of visible light 121 and the deepest penetrating power. It is suitable for any skin, promotes blood circulation, stimulates fibroblasts and collagen, accelerates the metabolism of melanin, increases oxygen and nutrient delivery, and has anti- The effect of aging, improving fine lines, removing spots, diminishing dark circles, and eliminating dullness, while also making skin smooth, delicate and elastic; blue light, with a wavelength of 468nm, has anti-inflammatory and sterilization functions, regulates cellular immunity, improves skin metabolism, and soothes Purify hair follicle inflammation and oil production. It is often used to inhibit acne bacilli, adjust sebaceous glands, treat acne, remove acne and improve skin problems such as enlarged pores; green light, with a wavelength of 525nm, is the basic hue of nature. Neutralization, balance and calming effect, can treat skin laxity, blackheads and acne caused by fatigue, and can reduce melanin production and improve skin dullness; yellow light, with a wavelength of 590nm, can promote cell metabolism and strengthen Blood and lymph circulation accelerates wound healing, metabolizes melanin, and can enhance the exchange effect of cellular oxygen, improve skin tone, and effectively absorb the nutrients of skin care products.

In more detail, the first sheet body 13 is irradiated with three different energy and wavelength visible light lasers (488nm, 532nm, 633nm) to make the laser pass through the transparent interface of the bioceramic sheet, and analyze the light passing through The energy difference between the front and rear; as shown in Figures 6 to 8, the first sheet 13 of this embodiment absorbs the infrared red photons in the visible light 121, and then emits a fixed emission lower than the original excitation light 0.361eV and The light energy of 0.368eV; this result shows that the light energy of 0.361eV and 0.368eV is located in the absorption band. In other words, this energy difference should be caused by the process of photoluminescence caused by light passing through the bioceramic boundary sheet In, the result of infrared light photons emitted during energy conversion. In addition, FIG. 9 shows the Brownian motion change of the test object 200 before and after the operation is measured by a laser trapping apparatus during operation.

Please refer to FIG. 10 and FIG. 11. FIG. 10 is a meridian energy analysis diagram before irradiation in the first embodiment of creation, and FIG. 11 is a meridian energy analysis diagram after irradiation in the first embodiment of creation. The low-frequency vibration wearable device 100 is irradiated on the twelve meridians of the test object 200. In this embodiment, the liver meridian is taken as an example. Before irradiation, the value of the liver meridian is more than 67.7, and after irradiation, the value of the liver meridian is between Between 35.2 and 56.3.

Therefore, it can be further understood from the above description that this creation uses the sound wave 226 and the infrared light 131 to act on the test object 200 at the same time to control the energy balance inside the test object 200 and increase liquid circulation and flow. Sex.

(Second embodiment)

Please refer to FIG. 12, which is a schematic diagram of the use state of the second embodiment of the creation. Compared with the first embodiment, the main structural difference of the second embodiment is that the wearing piece 30 is a necklace, and the low-frequency vibration wearing device 100 is worn on the neck of the test object 200, but This creation is not limited to this. In another preferred embodiment not shown in the figure, the wearing part 30 is a shoe or a helmet, and the lighting unit 10 and the low-frequency vibration unit 20 are assembled to the wearing part 30. In this way, the second embodiment can increase the application range of the low-frequency vibration wearable device 100 of the present invention.

It is worth mentioning that this creation system can control the output of the sound wave 226 and the visible light 121 according to the needs of the user. The control parameter settings used can include sound output pulse frequency, triangle wave, frequency, volume control and the visible light The wavelength of 121 can be adjusted according to the use requirements to achieve the best test and use effect.

It is worth mentioning that the test object 200 can be a liquid in an animal or a plant or a liquid in a static object.

Hereby, the characteristics of this creation and its expected effects are stated as follows:

The low-frequency vibration wearable device 100 of the present creation is mainly based on the arrangement of the first piece 13 and the second piece 21, and the arrangement of the wearing part 30, so that the low-frequency vibration wearable device 100 can be stably equipped Is worn on the test object 200, and the visible light 121 excites the first sheet 13 to irradiate the infrared light 131, and the first sheet 13 and the second sheet 21 can absorb the visible light 121 The characteristics of the infrared light photons can be used for the sound wave 226 and the infrared light 131 output by the low-frequency vibration wearable device 100 of the present creation when it is in operation, which can then control and or increase the Brownian inside the test object 200 Movement; more specifically, the sound wave 226 and the infrared light 131 are used to control the internal energy balance of the test object 200 and increase liquid circulation and fluidity.

In this way, this creative department has the following implementation and technical effects:

First, the present creation enables the low-frequency vibration wearable device 100 to be stably worn on the test object 200 through the arrangement of the wearing part 30, so that the low-frequency vibration wearable device 100 has the advantage of being convenient to carry and can be used when going out or traveling. At the same time, it takes into account the functions of entertainment and alleviating fatigue and insomnia, and continues to exert its effects.

Second, this creation is through the arrangement of the first sheet 13 and the second sheet 21, the first sheet 13 and the second sheet 21 have the characteristic of absorbing infrared photons in the visible light 121, and It has the characteristic of emitting infrared photons in the visible light 121, and irradiates the test object 200 in a physical way, so as to solve the relatively limited problem of the Brownian motion of water molecules in the body, and its infrared light absorption characteristics can be controlled during operation The hydrogen bonds of water molecules change, increasing the circulation or fluidity of water, blood or other liquids.

Third, this creation is based on the arrangement of the lighting unit 10 and the low-frequency vibration unit 20, which can control and or increase the Brownian motion inside the test object 200, and the sound wave 226 and the sound wave 226 can be combined and output by this creation. The infrared light 131 can control the energy balance inside the test object 200 and increase the liquid circulation and fluidity.

Fourth, this creation uses the non-invasive sound wave 226 and the infrared light 131 to replace the traditional invasive method to improve the internal effect of the test object 200.

To sum up, this creation has its excellent progress in similar products. At the same time, we have checked the domestic and foreign technical data about this type of structure, and the same structure has not been found in the literature. Therefore, this At the time of creation, the new patent requirements were already in place, and Yan filed an application according to law.

However, the above-mentioned are only the preferred and feasible embodiments of this creation. If there is no obvious conflict between the embodiments, the features can be combined with each other and replaced. In addition, any equivalent structural changes made by applying the specification of this new model and the scope of patent application should be included in the scope of patent of this creation.

100: Low-frequency vibration wearable device 10: Lighting unit 11: Lamp holder 12: Light-emitting parts 121: Visible light 13: The first piece 131: infrared light 20: Low frequency vibration unit 21: The second piece 22: Horn 221: Frame 222: Magnetic return 2221: groove 223: Bullet Wave 224: Magnetic cylinder 225: voice coil 226: Sound Wave 30: Wearables 200: test object

Figure 1 is a perspective view of the first embodiment of the creation. Figure 2 is a schematic diagram of the first embodiment of the creation. Figure 3 is an exploded view of the low-frequency vibration unit of the first embodiment of the creation. Figure 4 is an exploded view of the lighting unit of the first embodiment of the creation. Figure 5 is a schematic diagram of the use state of the first embodiment of the creation. Fig. 6 is a diagram of the luminescence spectrum and energy distribution of the glass sheet of the first embodiment of the creation. FIG. 7 is a diagram of the luminescence spectrum and energy distribution of the glass sheet of the first embodiment of the creation. FIG. 8 is a diagram of the luminescence spectrum and energy distribution of the glass sheet of the first embodiment of the creation. Fig. 9 is an analysis diagram of the Brownian motion of small molecules in the liquid recorded through the laser light clamp experiment in the glass sheet of the first embodiment of the creation. Figure 10 is a graph of energy analysis of the meridians before irradiation of the first embodiment of the creation. Fig. 11 is an analysis diagram of meridian energy after irradiation in the first embodiment of the creation. Figure 12 is a schematic diagram of the use state of the second embodiment of the creation.

100: Low-frequency vibration wearable device

10: Lighting unit

20: Low frequency vibration unit

30: Wearables

Claims (10)

A low-frequency vibration wearable device, which contains: A lighting unit, the lighting unit includes a lamp holder, at least one light-emitting element and a first sheet body, the light-emitting element is arranged in the lamp base, the first sheet system is connected to the lamp base and covers the light-emitting element ； A low-frequency vibration unit, the low-frequency vibration unit is electrically connected to the lighting unit, the low-frequency vibration unit includes a second plate and a horn, the horn includes a frame, a magnetic return member and a spring wave, the first The two-piece system is arranged on the frame, the magnetic return piece is arranged on the bottom side of the frame, a groove is recessed in the middle position of the magnetic return piece, and a magnetic column and a magnetic cylinder are arranged at the middle position of the groove. A voice coil, the voice coil is sleeved on the magnetic cylinder with linear displacement, and the middle position of the elastic wave is sleeved on the voice coil; and A wearable piece connected to the lighting unit and the low-frequency vibration unit, and the wearable piece is arranged on the outer periphery of the lighting unit and the low-frequency vibration unit, and the wearable piece is worn on a test object ； Wherein, the light-emitting element emits a visible light outwards, the wavelength of the visible light is between 380nm and 750nm, the first sheet body and the second sheet system are selected from one of a bioceramic sheet and a plant sheet or In combination, the visible light system irradiates the first sheet body and excites the first sheet body to irradiate an infrared light outward, and the first sheet body and the second sheet system are capable of absorbing infrared photons in the visible light Characteristics: The horn emits a sound wave, the frequency of the sound wave is between 10 Hz and 200 Hz, and the sound wave and the infrared light system act on the object under test simultaneously. For example, the low-frequency vibration wearable device of claim 1, wherein the wearable piece is a watchband, and the wearable piece is flexible. Such as the low-frequency vibration wearable device of claim 1, wherein the first sheet body and the second sheet system have flexibility, and the first sheet body and the second sheet system have characteristics of emitting infrared photons in the visible light . The low-frequency vibration wearable device of claim 1, wherein the first sheet body and the second sheet system are bioceramic sheets, and the first sheet body and the second sheet body contain a plurality of oxide mineral particles. According to the low-frequency vibration wearable device of claim 1, wherein the wavelength of the first sheet body to absorb infrared photons includes mid-infrared light of 2.75 μm to 3.59 μm. According to the low-frequency vibration wearable device of claim 1, wherein the wavelength of the first sheet body to absorb infrared photons includes far-infrared light of 6 to 20 microns. According to the low-frequency vibration wearable device of claim 1, wherein the first sheet body and the second sheet system are selected from one of a thin sheet body, a thick sheet body and a film. Such as the low-frequency vibration wearable device of claim 1, wherein the first sheet body and the second sheet system are plant sheets. Such as the low-frequency vibration wearable device of claim 1, wherein the oxide mineral particles are evenly distributed in the one piece and the second piece. Such as the low-frequency vibration wearable device of claim 1, wherein the oxide mineral particles comprise a plurality of alumina particles.

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