TWM490873U - Wearable physiological conditioning device using resonant wave - Google Patents

Description

Wearable resonance wave physiological conditioning device

The invention discloses a wearable resonance wave physiological conditioning device, in particular to a wearable physiological conditioning technology which can contribute to human health.

According to the conventional method, the low-frequency, medium-frequency or high-frequency electric therapy device is mainly used to output a weak current pulse to the human body at a fixed frequency within a working period. Since the conventional electrotherapy device does not have the function of generating a corresponding resonance wave formula for human diseases, the weak current pulse of the output does not have a resonance effect with human cells or organ tissues, so that the weak current pulse of the output can only be It acts on the surface of the human skin. Therefore, the conventional structure can only be used for relieving muscle pain and relaxing muscles, and cannot effectively regulate the physiological and organ tissues of the human body.

Furthermore, representative patents for combining wearable articles with low-frequency electrotherapy devices are shown in the patents such as "Nuclear Medical Device" of the Republic of China, No. M303026, and "Ophthalmic Massage Electrode Device" of the Republic of China, No. M471601. Although these patents can transmit low-frequency waves to the human body through wearing components (such as gloves, socks or wearing fabrics), these patents also have no function of generating a corresponding resonance wave formula for human diseases, so the output is The weak current pulse does not have a resonance effect with human cells or organ tissues, so that the weak current pulse of its output can only act on the surface of human skin. Therefore, the conventional structure can only be used to relieve muscle pain. As well as relaxing muscles and other uses, it is also impossible to effectively regulate the body's physiological organs.

In order to achieve the use of resonance waves to improve the health of the human body, the applicant Long-term active investment in human resources and money for research and development, and early development of a patent application as shown in the Republic of China Invention Application No. 100130621 "Bioresonance Wave Acting on Biological Control Systems and Methods", the main technical core of the patent is Design a resonance wave that can resonate with the frequency at the human body to have a beneficial effect on the human body; however, the patent does not relieve cardiovascular disease, slow down diabetes factor, cellular metabolic conditioning, and cell fluid conditioning. The function of the resonance wave formula of physiological conditioning is established. Therefore, the frequency of the resonance wave can only be set according to the empirical analysis inference, and then the periodic modulation correction is performed for the action frequency, in order to find a better and feasible frequency band. Therefore, although the patent case has a certain effect, there is still the need for further research and development. Since the resonance wave has specific and good effects on the diseases, mental state and growth of the human body or other animals and plants, it has become a technology that the relevant technical fields are vying for production and R&D. However, it is necessary to develop a Resonance wave technology, which is non-pharmaceutical and can promote the prevention and care mechanism of human cell metabolism, requires long-term in-depth research and development and testing.

In view of the fact that bioresonance waves have a great potential effect on the treatment or physiological relief of human diseases, and the aforementioned patents and prior art do not have a set of functions of combining a wear object and a resonance wave formula of a specific energy density, the present invention is Actively researching and developing, through practice and experiment, finally developed a new type that can regulate the body's physiological physique.

The main purpose of the novel is to provide a wearable resonance wave physiological conditioning device. It is mainly used by the human body to achieve the purpose of easy to wear and operate the resonance wave, and then resonate with the human body vibration frequency to produce health benefits. The technical means for achieving the main purpose of the novel include a resonance wave generator, a frequency output unit, and a wear component. The resonance wave generator is for outputting a resonance wave having a frequency of energy density (ED). The frequency output unit includes an electric energy wave output terminal for covering the body part of the user. The wear component can be worn on the user, and the wear component can be provided with a resonance wave generator or an electrode chip set. When the resonance wave generator outputs a resonance wave, the resonance wave is transmitted to the user from the power wave output terminal through the frequency output unit. In the body, 俾 can emit a resonance wave that resonates with the frequency in the human body by the wearing convenience of the wearing component.

10‧‧‧Resonance wave generator

11‧‧‧Shell

110‧‧‧Clamping parts

12‧‧‧ Signaling Seat

13‧‧‧Control unit

14‧‧‧Operation interface

15;‧‧‧Database memory unit

16‧‧‧Drive unit

17‧‧‧ Waveform generating unit

20‧‧‧frequency output unit

21‧‧‧Power wave output terminal

21a‧‧‧electrode sheet

22, 32‧‧‧ wire sets

220, 320‧‧‧ signal plug

220a‧‧‧first signal plug

220b‧‧‧second signal plug

30‧‧‧ wearing components

30a‧‧‧ring kit

30b‧‧‧ headphone

30c‧‧ glasses

31‧‧‧phone body

33‧‧‧ Frame

34‧‧‧ lenses

35‧‧‧ nose pad

330‧‧‧ ear hanging section

331‧‧‧second signal socket

FIG. 1 is a schematic diagram of the implementation of the first application embodiment of the present invention.

FIG. 2 is a schematic diagram of the wearing implementation of the first application embodiment of the present invention.

3 is a schematic diagram of the implementation of the second application embodiment of the present invention.

4 is a schematic diagram of the implementation of a third application embodiment of the present invention.

FIG. 5 is a schematic diagram of implementation of a fourth application embodiment of the present invention

FIG. 6 is a schematic diagram of the wearing implementation of the fourth application embodiment of the present invention.

FIG. 7 is a schematic diagram of the implementation of the fifth application embodiment of the present invention.

FIG. 8 is a schematic diagram of the wearing implementation of the fifth application embodiment of the present invention.

FIG. 9 is a schematic diagram of the implementation of the sixth application embodiment of the present invention.

FIG. 10 is a schematic diagram of the implementation of the seventh application embodiment of the present invention.

Figure 11 is a block diagram showing the circuit function of the novel resonant wave generator. Attachment: The chart is a comparison table of resonance wave working conditions and energy density for each new period of action.

In order to allow your review committee to further understand the technical features of the new model and the technical means to achieve the new purpose, it will be described in detail with specific examples and with diagrams and annex diagrams: please refer to Figures 1, 2 and 11 The basic embodiments for achieving the novel object include technical features such as the resonance wave generator 10, the frequency output unit 20, and the wear component 30. The resonant wave generator 10 is disposed on the wear component 30, and is configured to sequentially follow the corresponding spectrum data in a plurality of active periods of the time series data according to a spectrum data and a time series data of a resonant frequency recipe. A resonant electrical energy wave that produces at least one energy density (ED). The frequency output unit 20 is in signal communication with the resonant wave generator 10. The frequency output unit 20 includes an electric energy wave output terminal 21 for covering the body part of the user. The wear component 30 can be worn on the user, and the wear component 30 can be used to set the resonance wave generator 10 or the power wave output terminal 21. When the resonance wave generator 10 outputs a resonance wave, the resonance wave is transmitted to the user's body by the power wave output terminal 21 via the frequency output unit 20.

Referring to FIG. 1 and FIG. 2 , the first application example of the present invention is shown. The frequency output unit 20 further includes an electrode chip group 21 a as the power wave output terminal 21 and a wire group 22 . One end of the wire group 22 is electrically connected to the electrode group 21a, and the other end of the wire group is connected to the resonant wave generator 10. The wear component 30 as shown in Figures 1 and 2 is a loop set 30a (e.g., a wristband) that can be worn on the user's body or limb. The resonance wave generator 10 includes a casing 11 and a resonance wave generator 10 is disposed in the ring set 30a (the two sides of the casing 11 are joined at two free ends). Housing 11 A signal socket 12 is provided. The other end of the wire set 22 has a signal plug 220 for inserting the signal connector 12 to form a signal connection. The housing 11 can be clamped and fixed to the ring set 30a, and can be transmitted through the electrode set 21a. The resonance wave output from the resonance wave generator 10 is conducted to the hand of the user.

Please refer to FIG. 3 for a second application embodiment of the present invention, the frequency The output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21, and a wire group 22. One end of the wire group 22 is electrically connected to the electrode group 21a, and the other end of the wire group is connected to the resonant wave generator 10. The wearing component 30 shown in FIG. 3 is a ring set 30a (such as a wristband) that can be worn on the limb of the user, and the inner ring surface of the ring set 30a is provided with an electrode sheet set 21a that can be attached to the body part of the user. The resonance wave generator 10 includes a housing 11. The wire group 22 is embedded in the ring set 30a, and is electrically connected to the electrode chip group 21a at one end thereof and communicates with the resonant wave generator 10 at the other end thereof, thereby passing through the ring set 30a. The electrode sheet group 21a conducts the resonance wave output from the resonance wave generator 10 to the user's hand.

Please refer to FIG. 4 for the third application example of the present invention, the frequency input The output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21, and a wire group 22. One end of the wire group 22 is electrically connected to the electrode group 21a, and the other end of the wire group is connected to the resonant wave generator 10. The wear component 30 as shown in Figure 4 is an annular set 30a (e.g., a belt) that can be worn on the body or limb of the user. The resonance wave generator 10 includes a casing 11 and a resonance wave generator 10 is disposed in the ring set 30a. The housing 11 is provided with a clamping member 110 for clamping the annular sleeve 30a, and a signal receiving base 12. The other end of the wire set 22 has a signal plug 220 for inserting the signal connector 12 to form a signal connection. The housing 11 can be clamped and fixed to the ring set 30a, and can be transmitted through the electrode set 21a. The resonance wave outputted by the resonance wave generator 10 is transmitted to the human body Inside.

Please refer to FIG. 5 and FIG. 6 for the fourth application embodiment of the present invention. The frequency output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21 and communicating with the resonance wave generator 10. The wear component 30 as shown in Figures 5 and 6 is a loop set 30a (e.g., a belt) that can be worn on the user's limb. The ring set 30a is provided with a resonance wave generator 10. The resonance wave generator 10 includes a housing 11 having an electrode sheet group 21a attached to a body portion of the user, and a resonance wave is transmitted through the electrode group 21a on the housing 11. The resonance wave output from the generator 10 is conducted to the human body.

Please refer to FIG. 7 and FIG. 8 for a fifth application embodiment of the present invention. The frequency output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21. The wear component 30 shown in Figures 7 and 8 is an earphone 30b. The earphone 30b includes two sound tube bodies 31 and a wire set 32 that can be worn on the ear of the user. One end of the wire group 32 is electrically connected to the electrode sheet group 21a, and the other end of the wire group 32 is connected to the resonant wave generator 10. The surface of the two-tone tube body 31 is provided with an electrode assembly 21a. The resonance wave generator 10 includes a housing 11. The housing 11 is provided with a signal socket 12, and the other end of the wire group 32 has a signal for plugging in the signal. The socket 12 is formed to form a signal-connected signal plug 320, and the resonance wave outputted from the resonance wave generator 10 can be transmitted to the human body through the electrode group 21a on the sound drum body 31.

Please refer to FIG. 9 for a sixth application embodiment of the present invention, the frequency The output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21 and a wire group 22. The wearing component 30 shown in FIG. 9 is the eyeglasses 30c. The glasses 30c include a frame 33, two lenses 34 disposed on the frame 33, and two nose pads 35 disposed on the frame 33 for covering the nose of the user. One end of the wire group 22 is electrically connected to the electrode sheet group 21a, and the other end of the wire group 22 and the resonance wave generator 10 signals are connected. The electrode sheet group 21a is disposed on the earloop portion 330 at both ends of the frame 33. The resonant wave generator 10 includes a housing 11 , the housing 11 is provided with a signal socket 12 , and the frame 33 is provided with a second signal socket 331 . One end of the wire set 22 has a first signal plug 220a for plugging in the second signal socket 331 to form a signal connection, and the other end of the wire set 22 has a signal connector 12 for plugging in the signal connection 12 to form a signal connection. The second signal plug 220b can transmit the resonance wave outputted by the resonance wave generator 10 to the human body through the electrode group 21a on the two-ear suspension section 330.

Please refer to FIG. 10 for the seventh application embodiment of the present invention. The rate output unit 20 further includes an electrode sheet group 21a as an electric energy wave output terminal 21 and a wire group 22. One end of the wire group 22 is electrically connected to the electrode sheet group 21a, and the other end of the wire group 22 is connected to the resonant wave generator 10. The wearing component 30 shown in FIG. 10 is the eyeglasses 30c. The glasses 30c include a frame 33, two lenses 34 disposed on the frame 33, and two nose pads 35 disposed on the frame 33 for covering the nose of the user. The surface of the two nose pads 35 is provided with an electrode assembly 21a. The resonant wave generator 10 includes a housing 11. The housing 11 is provided with a signal socket 12, and the frame 33 is provided with a second signal socket 331. One end of the wire set 22 has a first signal plug 220a for plugging in the second signal socket 331 to form a signal connection, and the other end of the wire set 22 has a signal connector 12 for plugging in the signal connection 12 to form a signal connection. The second signal plug 220b can transmit the resonance wave outputted from the resonance wave generator 10 to the human body through the electrode group 21a on the two nose pads 35.

Specifically, please refer to FIG. 11 together, the resonant wave generator 10 includes A control unit 13 (such as a microprocessor), an operation interface 14 (such as a screen and a button as shown) for storing a resonance signal output mode of a resonance frequency recipe required by a user, and a storage resonance The data storage unit 15 of the frequency profile and the time series data storage unit 15 (such as built in the memory element), a driving unit 16 (such as a PWM driving module or a driving circuit) and a waveform generating unit 17 (such as Pulse wave or square wave generation circuit). The control unit 13 reads the corresponding spectrum data and the timing data in the library memory unit 15 according to the set resonant wave output mode, and generates a control signal for triggering the driving unit 16, thereby driving the waveform generating unit 17 The resonant wave is output. Further, the above-mentioned resonance wave output mode is a plurality of resonance wave formulas built in the data storage unit 15, such as a soothing cardiovascular disease resonance wave formula, a slowing diabetes factor resonance wave formula, and an immunity enhancing resonance wave formula. , cell metabolism conditioning resonance wave formula and cell water liquid conditioning resonance wave formula. As shown in the attached chart, each of the above energy densities is calculated by an energy density calculation formula, which is expressed by the following equation: Energy Density (ED) = log 10 (Freq. × Duty Cycle (D%) ×(2Width+1)×Total Time(TT)+1) Energy density (ED)=log10 [Frequency (Freq.) x duty cycle emissivity (D%)] x [2 scan width (Width) +1] x [time period of action (TT) +1]. Taking the first frequency action period as an example, assume that when the first frequency Freq.=22113.7hz, the duty cycle emissivity D%=70%, the scan width (ie bandwidth) Width=0, the time period TT = 2 seconds (sec), the calculation is as follows: ED = log (22113.7 x 70% x (2 x 0 + 1) x 2 + 1) = 4.49.

Since the above-mentioned resonant wave formula has been filed by the applicant, the simple explanation of the immune-enhancing resonance wave formula is as follows: please refer to the attached chart, firstly to the resonance wave generator. 10 establishing an immunity-enhancing resonance wave formula containing at least six frequency action periods, so that the resonance wave generator 10 sequentially outputs the corresponding electric energy waves in the first to sixth order according to the fine immunity lifting resonance wave recipe; The resonance wave is introduced through the arrangement of the wearable component 30 to act on the human body. First, the first energy density generation period in the first active frequency period is entered. When the energy wave generator 10 of the present invention starts to operate, the specific frequency of the electric energy wave is emitted to the human body, and the first will advance. Entering a first energy density generation period in a first active frequency period, wherein the frequency of the first energy density generation period is a single frequency scanning mode, and the first frequency (freq) is between 22107hz and 22120hz Preferably, the original fundamental frequency is 22107hz, the base frequency is 22115.5hz (the original fundamental frequency is the true transmission frequency, and the base frequency is obtained by random processing), and the energy density of the current period is the first energy density is 4.49. The duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 2 seconds. Here, it must be stated that the so-called single-frequency scan mode is for each The frequency of action is a fixed frequency until the end of the action time. Taking the first energy density generation period as an example, assuming that the first frequency is 22107 hz, the first frequency (freq) of the first energy density action period is fixed. 22107hz, until the frequency action time reaches 2 seconds, then enters the next energy density period, and so on, and since the single frequency scan mode has no range of frequency variation, the scan width (ie, bandwidth) 0hz; the frequency of the second energy density generation period is also a single frequency scanning mode, and the second frequency (freq) is between 15036hz and 15050hz, and the preferred original fundamental frequency is 15036hz, and the base frequency is 15040.7hz. The duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 7 seconds; the frequency of the third energy density generation period is the single frequency scan mode, the third frequency (freq) is between 10000hz and 10010hz, preferably the original fundamental frequency is 10000hz, the substrate frequency is 10000.4hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) ) is 12 seconds; the frequency of the fourth energy density generation period is a single frequency scanning mode, and the fourth frequency (freq) is between 5000hz and 5010hz, preferably the original fundamental frequency is 5000hz, and the base frequency is 5004.8hz. The duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 21 seconds; the frequency of the fifth energy density generation period is the single frequency scan mode, the fifth frequency (freq) is between 4442hz and 4460hz, preferably the original fundamental frequency is 4442hz. The substrate frequency is 4447.6hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 23 seconds; the frequency of the sixth energy density generation period is the scan increment. Mode, the sixth frequency (freq) is between 3175hz and 3190hz, preferably the original fundamental frequency is 3175hz, the substrate frequency is 3183.2hz, the duty cycle emissivity (D%) is 70%, and the scan width (Width) is 2hz. The action time (TT) is 27 seconds; in addition, the frequency wave output sequence of the scan increment mode is as shown in FIG. 5, and the frequency value change calculation method is: the first output frequency is the base frequency Fn minus the scan width m The second output frequency is the first output frequency plus a modulation variable (such as 1hz). When the next output frequency is equal to the base frequency Fn, the next output frequency is the last output frequency. For example, the sixth frequency ( Freq) is 3183.2hz, the scan width (Width) is 2hz, the number of frequencies can be determined according to the above formula is 3, and the output order of frequency is 3181.2hz, 3182.2hz, and 3183.2hz, respectively. The action time is 9 seconds, and the total action time (TT) of the 3 frequencies is 27 seconds. TT = (M + 1) * T.

Then, entering the seventh energy density generation in the second active frequency period During the period, the frequency of the seventh energy density generation period is a single frequency scanning mode, and the seventh frequency (freq) is between 2411hz and 2420hz, preferably the original fundamental frequency is 2411hz, the base frequency is 2415.3hz, and the duty cycle is transmitted. The rate (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 31 seconds; the frequency of the eighth energy density generation period is the single frequency scan mode, and the eighth frequency (freq) Between 1972hz~1980hz, the preferred original fundamental frequency is 1972hz, the substrate frequency is 1978.9hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 33. Second; the frequency of the ninth energy density generation period is a single frequency scanning mode, the ninth frequency (freq) is between 1823hz and 1830hz, preferably the original fundamental frequency is 1823hz, the base frequency is 1829hz, and the working period emissivity is (D%) is 70%, and the scan width (Width) is 0hz. The interval (TT) is 34 seconds; the frequency of the tenth energy density generation period is a single frequency scanning mode, the tenth frequency (freq) is between 1644hz and 1650hz, preferably the original fundamental frequency is 1644hz, the base frequency For 1651.6hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 0hz, the action time (TT) is 36 seconds; the frequency of the eleventh energy density generation period is single-frequency scan. Mode, the eleventh frequency (freq) is between 1550hz and 1565hz, preferably the original fundamental frequency is 1550hz, the substrate frequency is 1554.1hz, the duty cycle emissivity (D%) is 70%, and the scan width (Width) is 0hz, the action time (TT) is 36 seconds.

Then entering the twelfth energy density generation in the third active frequency period During the period, the frequency of the twelfth energy density generation period is the scan increment mode, and the twelfth frequency (freq) is between 522hz and 530hz, preferably the original fundamental frequency is 522hz, the base frequency is 524.9hz, and the duty cycle is The emissivity (D%) is 70%, the scan width (Width) is 2hz, and the action time (TT) is 51 seconds. The frequency of the thirteenth energy density generation period is the scan decrement mode, the thirteenth frequency ( Freq) is between 510~520hz, preferably the original fundamental frequency is 510hz, the substrate frequency is 516.1hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 2hz, and the action time (TT) For 51 seconds, in addition, the frequency of the sweep decrement mode is shown in Figure 4. The frequency value is calculated as follows: the first output frequency is the base frequency Fn plus the scan width m; the second output frequency is The first output frequency is subtracted from the one-modulation variable (eg 1hz). When the next output frequency is equal to the base frequency Fn, the next output frequency is the last output frequency. For example, the thirteenth frequency (freq) is 516.1hz, the scan width (Width) is 2hz, the number of frequencies can be determined according to the above formula is three, and the output order of the frequency is 514.1hz, 515.1hz and 516.1 respectively. Hz, each frequency action time is 17 seconds, the total action time (TT) of the three frequencies is 51 seconds, that is, TT=(M+1)*T; the frequency effect mode of the fourteenth energy density generation period is Scan increment mode, fourteenth frequency (freq) Between 464hz and 480hz, the preferred original fundamental frequency is 464hz, the substrate frequency is 467.5hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 5hz, and the action time (TT) is 54. Second; the frequency of the fifteenth energy density generation period is a single frequency scanning mode, the fifteenth frequency (freq) is between 442hz and 460hz, preferably the original fundamental frequency is 442hz, and the base frequency is 446.2hz, working The period emissivity (D%) is 70%, the scan width (Width) is 0hz, and the action time (TT) is 53 seconds.

Then enter the sixteenth energy density generation in the fourth active frequency period During the period, the frequency of the sixteenth energy density generation period is the scan convergence mode, the sixteenth frequency (freq) is between 860hz and 870hz, preferably the original fundamental frequency is 860hz, the base frequency is 869.4hz, and the duty cycle The emissivity (D%) is 70%, the scan width (Width) is 7hz, and the action time (TT) is 45 seconds. In addition, it must be noted that the frequency of the scan convergence mode is as shown in FIG. The frequency value change calculation method is: the first output frequency is the base frequency Fn plus the scan width m; the second output frequency is the base frequency Fn minus the scan width m; the third output frequency is the first output frequency Subtract one variable (such as 1hz); the fourth output frequency is the second output frequency plus one variable (such as 1hz), and so on, when the next output frequency is equal to the base frequency, then the next output frequency is For the last output frequency, for example, the 16th frequency (freq) is 869.4hz and the scan width (Width) is 7hz. According to the above formula, the number of frequencies can be 15, as for the frequency output. The order is 876.4hz, 862.4hz, 875.4hz, 863.4hz 874.4hz, 864.4hz, 873.4hz, 865.4hz, 872.4hz, 866.4hz, 871.4hz, 867.4hz, 870.4hz, 868.4hz and 869.4hz, the action time of each frequency is 3 seconds, the total action time of 15 frequencies (TT) is 45 seconds, that is, TT=(2M+1)*T; the frequency of the seventeenth energy density generation period is in the scan increment mode, and the seventeenth frequency (freq) is between 823hz and 840hz. Preferably, the original fundamental frequency is 823hz, the base frequency is 832.7hz, the duty cycle emissivity (D%) is 70%, and the scan width (Width) 8hz, the action time (TT) is 45 seconds; the frequency of the eighteenth energy density generation period is the scan convergence mode, and the eighteenth frequency (freq) is between 801hz and 810hz, preferably the original fundamental frequency is 801hz, the substrate frequency is 801.6hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 6hz, the action time (TT) is 39 seconds; the frequency of the nineteenth energy density generation period is Scan convergence mode, the nineteenth frequency (freq), between 781hz~790hz, preferably the original fundamental frequency is 781hz, the base frequency is 787.5hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 7hz, and the action time (TT) is 45 seconds.

Then, the third energy density is generated in the fifth active frequency period During the period, the frequency of the first energy density generation period is the scan increment mode, the third frequency (freq) is between 346 and 360 hz, preferably the original fundamental frequency is 346 hz, the base frequency is 347.2 hz, and the duty cycle emissivity is (D%) is 70%, the scan width (Width) is 9hz, and the action time (TT) is 60 seconds; the frequency of the first energy density generation period is the scan convergence mode, the first frequency (freq) Between 338 and 350hz, the preferred original fundamental frequency is 338hz, the substrate frequency is 338.7hz, the duty cycle emissivity (D%) is 70%, the scan width (Width) is 7hz, and the action time (TT) is 60. Second; the frequency of the second energy density generation period is the scan convergence mode, the second frequency (freq) is between 248 and 260hz, preferably the original fundamental frequency is 248hz, the base frequency is 254.8hz, the duty cycle The emissivity (D%) is 70%, the scan width (Width) is 6hz, and the action time (TT) is 65 seconds.

Finally entering the third energy density generation in the sixth active frequency period During the period, the frequency of the third energy density generation period is the scan decreasing mode, and the third frequency (freq) is between 33 and 42 hz, preferably the original fundamental frequency is 33 hz, the base frequency is 42.1 hz, and the duty cycle is The emissivity (D%) is 70%, the scan width (Width) is 7hz, and the action time (TT) is 88. Second; the frequency of the fourth energy density generation period is the scan convergence mode, the fourth frequency (freq) is between 13~23hz, preferably the original fundamental frequency is 13hz, the base frequency is 22.1hz, the duty cycle The emissivity (D%) was 70%, the scan width (Width) was 7 hz, and the action time (TT) was 105 seconds.

Therefore, the present invention is illustrated by the human body by the above specific embodiments. The configuration is to achieve the purpose of convenient operation and use of resonance waves, and thus resonate with the vibration frequency of the human body, thereby achieving many health benefits such as soothing cardiovascular diseases, slowing down diabetes factors, improving immunity, cell metabolism conditioning, and cell fluid conditioning. The effect.

The above is only a feasible embodiment of the present invention, and is not intended to limit the present invention. The scope of the patents, the equivalent implementations of other variations in accordance with the content, features and spirit of the claims below, are intended to be included in the scope of the invention. The new type is specifically defined in the structural features of the request item, is not found in similar items, and has practicality and progress. It has met the requirements of the new patent, and has applied for it according to law. The legal rights of the applicant.

10‧‧‧Resonance wave generator

11‧‧‧Shell

12‧‧‧ Signaling Seat

14‧‧‧Operation interface

20‧‧‧frequency output unit

21‧‧‧Power wave output terminal

21a‧‧‧electrode sheet

22‧‧‧Wire set

220‧‧‧Signal plug

30‧‧‧ wearing components

30a‧‧‧ring kit

Claims (10)

A wearable resonance wave physiological conditioning device includes: a wear component that can be worn on a user; a resonance wave generator disposed on the wear component for formulating a resonance frequency The spectrum data and the time series data, in the plurality of active periods of the time series data, sequentially generate at least one energy density (ED) resonant energy wave according to the corresponding spectrum data; and a frequency output unit, which comprises one And an electric energy wave output terminal that is in contact with the body part of the user, and is connected to the resonant wave generator signal for outputting the resonant electric energy wave generated by the resonant wave generator and passing through the electric energy wave output terminal Acts on the user's body. The wearable resonance wave physiological conditioning device according to claim 1, wherein the resonance wave generator comprises a control unit, and a resonance wave output mode of the resonance frequency recipe is required for the user to select and select. An operation interface, a data storage unit for storing the spectrum data of the resonance frequency formula and the time series data, a driving unit and a waveform generating unit, wherein the control unit reads the resonance wave output mode according to the set Corresponding the time series data and the spectrum data in the data storage unit, and generating a control signal for triggering the driving unit, thereby driving the waveform generating unit to output the resonant wave. The wearable resonance wave physiological conditioning device of claim 1, wherein the frequency output unit further comprises an electrode sheet group as the power wave output terminal, and a wire group, and one end of the wire group is electrically connected to the electrode sheet The other end is connected to the resonant wave generator. The wearing component is a ring set that can be worn on the body or limb of the user, and the resonant wave generator is disposed in the ring set. The wearable resonant wave physiological conditioning device of claim 3, wherein the resonant wave generator comprises a housing, and a clamping member for clamping the annular sleeve is disposed on the inner surface of the housing. The wearable resonance wave physiological conditioning device of claim 1, wherein the frequency output unit further comprises an electrode sheet group as the power wave output terminal, and a wire group, and one end of the wire group is electrically connected to the electrode sheet The other end is connected to the resonant wave generator. The wearing component is a ring set that can be worn on the body or limb of the user. The inner ring of the ring set is disposed to cover the user. In the electrode assembly, the resonance wave generator comprises a casing embedded in the annular sleeve and electrically connected to the electrode assembly at one end thereof and communicated with the resonance wave generator at the other end. The wearable resonance wave physiological conditioning device according to claim 1, wherein the frequency output unit further comprises an electrode sheet group as the power wave output terminal and communicating with the resonance wave generator signal, wherein the wearing component is a ring set for the user's body or limb, the ring set is disposed on the resonant wave generator, the resonant wave generator includes a casing, and the inner surface of the casing is disposed to be attached to the electrode piece of the user group. The wearable resonance wave physiological conditioning device of claim 1, wherein the frequency output unit further comprises an electrode sheet group as the power wave output terminal, the wearing component is an earphone, and the earphone comprises two for wearing a sound tube body of the user's ear and a wire group, one end of the wire group is electrically connected to the electrode chip group, and the other end of the wire group is connected to the resonance wave generator signal, and the electrode is respectively disposed on the surface of the two sound tube body Slice group. The wearable resonance wave physiological conditioning device of claim 1, wherein the frequency output unit further comprises an electrode sheet group as the power wave output terminal and a wire group, and one end of the wire group and the electrode sheet group are electrically connected. The other end of the connection is connected to the resonant wave generator. The wearing component is a pair of glasses. The eyeglasses include a frame, two lenses disposed on the frame, and two frames disposed on the frame for the user to be attached to the frame. a nose pad on the nose, the electrode pad is respectively disposed on the surface of the two nose pads group. The wearable resonance wave physiological conditioning device according to claim 1, wherein the frequency output unit further comprises an electrode sheet group and a wire group as the power wave output terminal, the wearing component is a pair of glasses, and the glasses comprise a lens. a lens frame, two lenses disposed on the frame, and two nose pads disposed on the nose of the user frame, the one end of the wire group being electrically connected to the electrode pad group, and the other end of the wire group and the resonant wave The generator signals are connected, and the electrode sheets are disposed on the ear hook segments at the two ends of the frame. The wearable resonance wave physiological conditioning device of claim 7, wherein the resonant wave generator comprises a casing, the casing is provided with a signal socket, and the other end of the wire group has a socket for inserting the The signal is connected to form a signal plug that is connected to the signal.