KR20180134514A - Smart device with function providing wave - Google Patents

Abstract

An embodiment of the present invention relates to a smart device having a wave providing function, and a technical problem to be solved is to minimize a size of a stimulus generator by using a minimum amount of current in the frequencies of LF, MF, HF, and VHF bands, and to enable the driving of the stimulus generator to be controlled through an application installed in the smart device by coupling or connecting the stimulus generator to the smart device. According to an embodiment of the present invention, the smart device having a wave providing function comprises: a low-frequency stimulator generating a fine current having a wavelength of a sawtooth wave and transmitting the generated fine current to the human body; and a smart device provided with the low-frequency stimulator, having a driving application installed for the low-frequency stimulator, and controlling the operation of the low-frequency stimulator by executing the driving application.

Description

TECHNICAL FIELD [0001] The present invention relates to a smart device having a wave providing function,

One embodiment of the present invention relates to a smart device having a wave providing function.

In recent years, interest in health has been gradually increasing in the background of rich material culture. In addition, due to changes in the diet culture and lack of exercise, various kinds of adult diseases have become more interested in health. Accordingly, various functions and kinds of beauty related devices have been developed and widely used. Electric therapy equipment is one of them.

Electrical therapy can be defined as a field of medical science that diagnoses and treats diseases using electricity such as direct current, alternating current, and pulsating current.

Electrotherapy includes medical galvanism therapy, iontoporesis, electrical stimulation theraphy (EST), transcutaneous electrical nerve stimulation (TENS) therapy, functional electrical stimulation therapy (FES), interferential current therapy (ICT) therapy, shortwave diathermy (SWD) therapy, microwave diathermy (MWD) therapy, and ultrasound therapy.

Such electric therapy is used for therapeutic purposes of musculoskeletal injuries and diseases, nervous system injuries and diseases, circulatory diseases, skin diseases, medical diseases, chronic inflammatory diseases and the like.

The greatest merit of such a treatment method using electron energy is known as a therapy which is advantageously used for treatment by causing an electrical change to the human body by electric stimulation from the outside using the phenomenon and characteristics of the body.

However, the electric treatment is remarkably different in function depending on the waveform of the frequency, the current, the intensity of the electric current, the application site, and the like. Particularly, different reactions occur depending on the structure, size, material and time of application of the plate to be applied to the body, the total amount of the treatment solution and the combination with the related antibiotic agent.

Both capacitive and resistive electric transfer produce a variety of biologic effects. That is, by increasing the internal temperature, it is possible to cause vasodilation, which can maintain the biological phenomenon associated with the vitality of the living tissue, thereby increasing blood circulation, improving nutritional and oxygen supply, improving intracellular respiration and toxic decomposition products stimulates the release of catabolin.

A conventional electric therapy apparatus is used by attaching a positive electrode pad and a negative electrode pad as an output device for applying electric stimulation to a specific region such as a waist, abdomen, leg, shoulder, soles of a body, etc., Frequency signals having the same frequency characteristics to deliver electrical stimulation to the body.

However, since the low-frequency current is transmitted only through the patch electrode pad directly attached to the affected part of the subject, the range of the electric stimulus is narrow and the treatment effect through the electric stimulation and the massage effect are somewhat insufficient. The electrical stimulation is transmitted to the subject physically, so that the physiological stimulus is transmitted to the physician as it is.

In addition, the conventional electric therapy apparatus has a problem that it is not easy to carry.

On the other hand, a permanent magnet is embedded in an ornamental gauss permanent magnet to obtain a health promoting effect by magnetic force, and a ceramic coated with a ceramic that emits a far-infrared ray to the ornament using a ceramic coating technique, There are some products that facilitate the metabolism to promote blood circulation and improve energy and eliminate the waste products of the human body, but they are disadvantageous in that the price is higher than the efficacy.

In the case of the permanent magnet, when a magnetic force line is irradiated to the whole blood flowing every several tens seconds, anion increases in the blood to affect the autonomic nerve, and consequently, a schematic theory that the endocrine stimulation and blood circulation are promoted and the disease is improved is induced Which is believed to support the above-mentioned therapeutic effect.

In particular, in the case of permanent magnets, when the magnetic force or the magnetic pole is not matched or when the magnetic property is used indiscriminately, the magnetic field of the human body is disturbed and the health is disturbed.

Patent Registration No. 10-15566193 (Registration Date: October 01, 2015)

An embodiment of the present invention minimizes the size of the stimulus generator using the frequency minimum currents of the LF, MF, HF, and VHF bands, and connects or connects the stimulator to the smart device, Provided is a smart device having a function of providing a wave to be controlled.

In an embodiment of the present invention, a smart device itself may be provided with a wave providing function capable of transmitting a minute current to a human body or connecting a stimulus generator worn on each part of the body to a smart device to transmit a minute current to every corner of the body Provide a smart device.

In addition, one embodiment of the present invention is a smart device having a function of providing a wave to exert a therapeutic effect such as massage, blood circulation relaxation, stress alleviation, and health improvement by minimizing electric stimulation by transferring a micro current to a human body Lt; / RTI >

A smart device having a wave providing function according to an embodiment of the present invention includes a low frequency stimulator for generating a fine current having a wavelength of a sawtooth wave and transmitting the generated fine current to a human body; And a smart device provided with the low frequency stimulator, an application for driving the low frequency stimulator, and a smart device controlling the operation of the low frequency stimulator by executing the driving application.

Wherein the low frequency stimulator is supplied with power from the smart device and outputs a predetermined switching control signal in response to a low frequency stimulation pattern control signal provided from the smart device; And a voltage conversion circuit unit for supplying the high / low voltage low current signal to the stimulating means in response to the switching control signal.

According to another aspect of the present invention, there is provided a smart device having a wave providing function, the smart device having a connection unit coupled to a connection terminal of a smart device, the smart device having a waveform of a sawtooth wave corresponding to a low- Wherein at least two electrodes for transmitting the generated microcurrent to the human body are provided at one end of the low frequency magnetic pole, and the smart device is provided with at least two electrodes for driving the low frequency magnetic stimulator, And the operation of the low frequency stimulator can be controlled by executing the driving application.

Wherein the driving application supplies a plurality of low frequency stimulation patterns of ELF, SLF, ULF, VLF, LF, MF, HF and VHF band frequencies according to a user's selection, wherein the low frequency stimulation patterns are vibration, massage, trembling, And the smart device may be capable of adjusting the time or intensity of the low frequency stimulation pattern.

A smart device having a wave providing function according to an exemplary embodiment of the present invention minimizes the size of the stimulus generator using the frequency minimum current amount in the ELF, SLF, ULF, VLF, LF, MF, HF, and VHF bands, The generator can be coupled to or connected to a smart device to control the drive through applications installed on the smart device.

In an embodiment of the present invention, a smart electric device can transmit a minute electric current to a human body or a micro electric current can be transmitted to every corner of a body by connecting a stimulus generator worn to each part of the body to a smart device, This makes it possible to easily provide a human body with a minute current using this waveform. Thus, one embodiment of the present invention can improve the convenience of electrical therapy.

In addition, an embodiment of the present invention can transmit a micro current to a human body and can exert therapeutic effects such as massage, blood circulation relaxation, stress relaxation, and health promotion effect by minimizing electric stimulation.

1 is a block diagram schematically showing a smart device having a wave providing function according to an embodiment of the present invention.
Fig. 2 is a block diagram showing an embodiment of a power supply unit applicable to Fig. 1. Fig.
3 is a diagram illustrating a smart device having a wave providing function according to another embodiment of the present invention.
4 is a view showing an embodiment of a smart device having a wave providing function according to another embodiment of the present invention.
5 is a flowchart showing an example of the operation of the power supply unit in Fig.
6 is a diagram illustrating an application example of a smart device having a wave providing function according to another embodiment of the present invention.

The terms used in this specification will be briefly described and the present invention will be described in detail.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

When an element is referred to as "including" an element throughout the specification, it is to be understood that the element may include other elements as well, without departing from the spirit or scope of the present invention. Also, the terms "part," " module, "and the like described in the specification mean units for processing at least one function or operation, which may be implemented in hardware or software or a combination of hardware and software .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

FIG. 1 is a block diagram schematically showing a smart device having a wave providing function according to an embodiment of the present invention. FIG. 2 is a block diagram showing an embodiment of a power source part applicable to FIG. 1, 2 is a flow chart showing an example of the operation of the power supply unit of Fig.

1, a smart device 100 having a wave providing function according to an exemplary embodiment of the present invention uses frequency minimum currents of ELF, SLF, ULF, VLF, LF, MF, HF, and VHF bands And includes a low-frequency stimulator 195 and a smart device 100. The low-

The low-frequency stimulator 195 generates a microcurrent having a sawtooth wave and transmits the microcurrent to the human body. The low frequency stimulator 195 generates the frequency and the output waveform of the frequency is generated as the sawtooth wave. When the power is supplied from the battery 182, the driving application is executed to generate the output waveform of the frequency as the sawtooth wave have.

The low-frequency stimulator 195 may include a PCB-type control unit 140 and a voltage conversion circuit unit 170, and a stimulation unit 190 that transmits a micro current to the human body. The control unit 140, the voltage conversion circuit unit 170, and the magnetic pole unit 190 may be inserted or attached to the smart device 100 in the form of a metal plate or a housing.

More specifically, the low-frequency stimulator 195 receives power from the smart device 100 and outputs a predetermined switching control signal in response to the low-frequency stimulation pattern control signal provided from the smart device 100 And a voltage conversion circuit unit 170 for supplying a high / low voltage low current signal to the stimulation means in response to the switching control signal.

The low-frequency magnetic stimulator 195 may output alternating-type rectangular waves at regular intervals through a single contact point, or may output alternating-current rectangular waves at regular intervals through two or more contact points. have.

The smart device 100 is provided with a low frequency stimulator 195 and an application for driving the low frequency stimulator 195. The device controls the operation of the low frequency stimulator 195 by executing a driving application. This may include a smart phone or a variety of smart devices that can replace it.

At this time, the driving application supplies a plurality of low frequency stimulation patterns of ELF, SLF, ULF, VLF, LF, MF, HF and VHF band frequencies according to the user's selection.

Information on each band frequency is shown in Table 1 below.

Band name frequency ELF (Extremely low frequency) 3 ~ 30Hz SLF (Super low frequency) 30-300 Hz ULF (Ultra low frequency) 300 to 3000 Hz Very low frequency (VLF) 3 to 30 kHz LF (Low frequency) 30 to 300 kHz Medium low frequency (MF) 300 to 3000 kHz HF (High frequency) 3 to 30 MHz Very high frequency (VHF) 30 to 300 MHz UHF (Ultra high frequency) 300 to 3000 MHz SHF (Super high frequency) 3 to 30 GHz Extremely high frequency (EHF) 30 to 300 GHz

The low-frequency stimulation pattern includes any one of vibration, massage, tremor, and pressure. The smart device 100 may be capable of adjusting the time or intensity of the low frequency stimulation pattern.

1, the control unit 140 fetches a control program for the low frequency stimulation function stored in the memory unit 160 and outputs the low frequency stimulation function to the smart device 100 to the operating state for performing the low frequency stimulation function. When the user selects the low frequency stimulation time or the low frequency stimulation intensity (level) through the operation unit 130, the user stores the low frequency stimulation intensity in the memory unit 160 And controls the display unit 150 at the same time.

The display unit 150 may display a function selected by the user (for example, a low frequency stimulation function), a low frequency stimulation intensity, and a low frequency stimulation time on the screen so that the user can easily operate the current state of the smart device 100 The remaining low frequency stimulation time and the like can be easily confirmed.

When the basic procedure for performing the low frequency stimulation function is completed, the control unit 140 applies a control signal to the voltage conversion circuit unit 170 to generate a low frequency. The voltage conversion circuit unit 170 receiving the control signal generates a waveform corresponding to the applied control signal and transmits the waveform to the low frequency stimulator 195. The low frequency stimulator 195 generates a low frequency using a low frequency circuit Amplifies and transmits the amplified signal to the stimulation unit 190 attached to or coupled to the smart device 100.

3 to 4, the waveforms of such minute currents may be transmitted to the body of the smart device itself, and may be connected to the respective parts of the body by utilizing connection means (for example, a jack) connected to the smart device So that every corner of the body can provide a microcurrent of the waveform.

Meanwhile. The smart device 100 basically includes a receiving unit 110 and a transmitting unit 120 for data transmission and reception.

The smart device 100 may include a power supply unit 180 for supplying power for each operation of the control unit 140 and the low frequency stimulator 195. In the present invention, The control unit 140 may be connected to the control unit 140 through a charging system.

Generally, in a battery such as a lithium ion battery or a lithium polymer battery, when the charge seed rate is increased so that the charging time is shortened, lithium ions are precipitated on the surface of the negative electrode active material (lithium plating) Is known to be shortened. Therefore, in the present invention, a configuration / method capable of suppressing the battery deterioration phenomenon and the life shortening phenomenon while reducing the charging time (rapid charging) will be described.

2, the power supply unit 180 according to various embodiments of the present invention may further include a thermoelectric element 183, a current regulator 184, and a charge mode selector 185. Each component constituting the power supply unit 180 may be implemented in an electronic device implemented for each function or in a driving application by programming.

The thermoelectric element 183 is installed on the surface of the battery 182 and serves to increase or decrease the temperature of the battery 182 according to the ambient temperature under the control of the controller 140. The thermoelectric element 183 can be a heat-generating surface on one side and a heat-absorbing surface on the other side in accordance with the flow direction of the current. Thus, the thermoelectric element 183 can be easily operated as a heat- can do.

The current regulator 184 is provided between the DC-DC converter 181 and the battery 182 and regulates the seed-rate supplied to the battery 182 under the control of the controller 140. The current regulator 184 may be implemented by an IGBT (Insulated Gate Bipolar Mode Transistor), a FET (Field Effect Transistor), a bipolar transistor, or the like, which is controlled by PWM (Pulse Width Modulation).

The charging mode selection unit 185 plays a role of receiving a rapid charging mode (for example, a 30-minute rapid charging mode) or a continuous charging mode (for example, a 3-hour sustained charging mode) by the user. The charging mode selection unit 185 basically selects the slow charging mode and transfers it to the control unit 140, for example, although it is not limited thereto. In addition, the charging mode selection unit 185 may be implemented by a key or a button structure.

The control unit 140 loads the temperature and / or the rate of the battery 182 per charging time and / or charging capacity corresponding to the charging mode selected by the user and stores the temperature of the battery 182 / RTI > and / or < / RTI > Of course, the controller 140 directly controls the thermoelectric element 183 and the current regulator 184 for this purpose.

The memory unit 160 stores the operation algorithm (program or software) of the control unit 140 described above and the temperature and / or the rate of the battery 182 per charging time and / or charging capacity according to the charging mode . The temperature and / or the seed-rate profile of such a battery 182 is stored in a pre-optimized value according to a number of experiments or simulations in the manufacture of the battery 182.

In this way, when the rapid charge mode is selected by the user, the controller 140 controls the temperature of the thermoelectric element (or the temperature sensor) to gradually decrease the temperature and the rate of the battery 182 from the highest value to the lowest value 183 and the current regulating unit 184, it is possible to shorten the charging time and minimize the deterioration of the battery 182 or the shortening of the life span.

For example, but not limited to, the control unit 140 may control the current regulator 184 to gradually decrease the seed-rate in a step-like manner, especially at a point where the level is different and / One charging stop time is further provided, so that the charging time can be further shortened. That is, the internal resistance of the battery 182 is reduced and stabilized when the charging current is supplied discontinuously, and the amount of charging current is reduced, rather than continuously supplying the charging current, so that the charging speed is faster and the deterioration phenomenon is smaller .

For example, the controller 140 may control the current regulator 184 to gradually decrease the seed-rate from about 5 C to 1 C in a stepwise manner, while controlling the temperature of the thermoelectric element 183 to 50 Deg.] C to 10 [deg.] C. Here, these numerical values are only examples for understanding the present invention, and the present invention is not limited to these numerical ranges.

Alternatively, the controller 140 may maintain the temperature of the battery 182 at approximately 20 ° C to 30 ° C using the thermoelectric element 183 when the user selects the slow charge mode, Also, the current regulator 184 can be controlled to maintain the seed-rate at approximately 0.1 C to 0.5 C. That is, although the charging time is prolonged in this temperature range and the seed-rate, the deterioration rate of the battery and the shortening of the lifetime are minimized.

In addition, although not shown in the drawing, a system according to an embodiment of the present invention includes a temperature sensor for sensing the temperature of the battery 182, a voltage sensor and / or a current sensor for estimating the capacity of the battery 182 It is natural.

As shown in FIG. 5, the wireless charging method of the power supply unit may include a step S1 of determining whether the charging mode is the rapid charging mode, a charging temperature for rapid charging and a loading step S2 for charging the charging rate, A temperature for slow charging and a loading step for a seed rate profile S4, a step S5 for confirming whether the charging is complete, and a charging stop step S6.

The controller 140 determines whether the rapid charging mode is selected by the user through the charging mode selector 185 in step S1. If the rapid charge mode is selected, step S2 is performed, otherwise step S3 is performed.

In the rapid charging temperature and seed-rate profile loading step S2, the control unit 140 loads the rapid charging temperature and the seed-rate profile per the charging time and / or the charging capacity stored in the memory unit 160. [

For example, the controller 140 controls the thermoelectric element 183 so that the temperature of the battery 182 is maintained at about 30 ° C to 50 ° C regardless of the ambient temperature at the beginning of charging, As the elapsed time or the charging capacity increases, the thermoelectric element 183 is controlled to load a profile that maintains the temperature of the battery 182 at approximately 20 ° C to 30 ° C. The control unit 140 controls the current regulator 184 to supply a current to the battery 182 in the form of a pulse having a charge rate of about 3 C to 5 C and a charge stop time And controls the current regulator 184 as the charge time elapses or the charge capacity increases so that the current is supplied to the battery 182 in the form of a pulse having a charge rate of 1 C to 2 C and a charge stop time of the battery 182 ) To be fed to the robot.

Meanwhile, in the step S3 of determining whether the mode is the full charge mode, the controller 140 determines whether the user has selected the full charge mode through the charge mode selector 185. [ When the slow charge mode is selected, step S4 is performed.

The control unit 140 loads the slowly charging temperature and the seed-rate profile per charging time and / or charging capacity stored in the memory unit 160 in the slow charging temperature and seed-rate profile loading step S4.

For example, but not limited to, the control unit 140 controls the thermoelectric element 183 to maintain the temperature of the battery 182 at approximately 20 ° C to 30 ° C regardless of the ambient temperature, and also controls the current regulator 184 ) To load a charge profile that maintains the seed-rate at approximately 0.1C to 0.5C.

In step S5, the controller 140 determines whether the current amount of the battery 182 is fully charged. The determination as to whether or not the battery 182 is fully charged can be performed by converting the battery voltage into SOC (State of Charge) or by measuring the total amount of charge injected into the battery 182. A method for determining whether the battery 182 is fully charged is well known to those skilled in the art, and therefore, a description thereof will be omitted.

If it is confirmed that the battery 182 is fully charged, step S6 is performed, otherwise, the process returns to step S1.

In the charging stop step S6, the control unit 140 controls the current regulating unit 184 so that the current is no longer supplied to the battery 182 so that the charging of the battery 182 is completed.

As described above, in the embodiment of the present invention, by supplying the pulse charging current relatively higher than the temperature of the relatively high battery 182 in the region where the capacity of the battery 182 is low, there is no precipitation of lithium ions, So that the battery 182 can be charged quickly. Here, if the battery 182 is charged with a relatively high pulse charge current in a state where the temperature of the battery 182 is approximately 0 ° C or lower, the aforementioned lithium ion precipitation and electrolytic decomposition phenomenon may occur and the battery 182 deteriorates severely Thus shortening the life span. However, as in the present invention, when the temperature of the battery is increased and the battery is charged at a high rate during the initial charging of the battery regardless of the ambient temperature, and the battery temperature is lowered and the battery is charged at the time of terminal charging at the end of the battery, It is possible to reduce deterioration and life shortening.

FIG. 3 is a view showing a smart device having a wave providing function according to another embodiment of the present invention, FIG. 4 is a view showing an embodiment of a smart device having a wave providing function according to another embodiment of the present invention And FIG. 6 is a diagram illustrating an application example of a smart device having a wave providing function according to another embodiment of the present invention.

3, a smart device having a wave providing function according to another embodiment of the present invention includes a connection unit 237 coupled to a connection terminal of the smart device 200, and is provided from a connection unit 237 And a low frequency stimulator (185 in FIG. 1) for generating a fine current having a wavelength of a sawtooth wave corresponding to the low frequency stimulation pattern signal of the smart device 200. The low frequency stimulator is provided at one end thereof with a human body At least two or more electrodes 231 are provided.

At this time, the smart device 200 is provided with an application for driving a low frequency stimulator, and can control the operation of the low frequency stimulator by executing a driving application.

The driving application supplies a plurality of low frequency stimulation patterns having LF, MF, HF, and VHF band frequencies according to a user's selection. At this time, the low-frequency stimulation pattern includes any one of vibration, massage, trembling, and pressing. In addition, the smart device may be capable of adjusting the time or intensity of a low frequency stimulation pattern.

3, a smart device having a wave providing function according to another embodiment of the present invention includes a smart device 200 (hereinafter referred to as a smart phone) on which a driving application for low frequency stimulation pattern control is mounted, And a low frequency stimulator 230 connected to the connection terminal 201 of the smart phone 200 to convert a signal corresponding to the low frequency stimulation pattern control into a high voltage low current signal and providing the signal to each electrode 231.

The smartphone 200 downloads a driving application for low frequency stimulation pattern control and supplies a plurality of types of low frequency stimulation patterns according to a user's selection. For example, it is possible to provide patterns such as vibration, massage, tremor, pressure, and the like. Accordingly, each pattern is displayed on the display window 203 of the smartphone 200, and an arbitrary pattern can be selected by the user or the time and intensity can be adjusted.

The low frequency stimulator 230 includes a connection unit 237 for coupling to the connection terminal 201 of the smartphone 200 and a low frequency stimulation pattern control signal for the smart phone 200 provided from the connection unit 237, A connector 239 constituted by a circuit housing 235 in which a voltage conversion circuit for converting a current into an electric current is inserted, an output terminal of the voltage conversion circuit through a signal line 233, And at least two electrodes 231.

3 illustrates that the connection terminal 201 of the smartphone 200 and the connection portion 237 of the low frequency stimulator 230 have a micro USB structure and are formed of 4 pins or 5 pins. However, But the present invention is not limited thereto and may be implemented with a connection terminal structure such as a general earphone or a headset.

For example, the micro USB may be applied as an A type or a B type having a 4-pin structure, or a MINI-A type, a MINI-B type, a Micro-A type or a Micro-B type having a 5-pin structure may be used. (+) Terminal, an ID terminal, and data (D +, D-) terminals, including a ground terminal (G) The application performs the low frequency stimulation pattern control to the connection unit 237 using the ID terminal and the data terminal.

3, the connector 239 receives power from the smartphone 200 through the connection unit 237, and simultaneously receives the power from the control unit (140 in FIG. 1) in response to the low frequency stimulation pattern control signal And outputs a switching control signal to the electrode 231 and supplies a high-voltage low-current signal to the electrode 231 in response to the switching control signal from the voltage conversion circuit portion 170 (FIG. 1).

At this time, based on the micro USB communication protocol, the controller receives ID information for selecting a type of a low frequency stimulation pattern from the smartphone 200 and data (D +, D) for performing switching control corresponding to the low frequency stimulation pattern -). Further, the electrode 231 is switched in response to the ID and the data D + and D-, and a pulse signal corresponding to the low-frequency stimulation pattern is output.

Accordingly, at least two or more electrodes are sequentially selected or overlapped by an electrode switching signal, and the voltage conversion circuit unit converts the pulse signal into a high-voltage low-current signal and supplies the high-voltage low-current signal to a selected arbitrary electrode.

As described above, the low-frequency stimulation pattern signal is selected by the user and can be a pattern such as vibration, massage, tapping, pressing, and the like. The display window 203 of the smartphone 200 displays a pattern / RTI >

As a result, the user connects the low-frequency stimulator 230 with the smartphone 200 to implement a low-frequency low-frequency stimulation function of high voltage and low current so that it can be usefully used in real life.

Accordingly, the low frequency stimulator 230 generates an electric stimulus signal to provide a low frequency stimulus to a specific body part of the user. The user can easily receive the low frequency massage by asking only the stimulation means for the specific body part for the low frequency treatment. Moreover, since the user uses the smart phone, it is convenient to carry, and the massage function can be used anytime and anywhere.

4, a smart phone or a smart watch may be applied to the smart device 200, and a low frequency stimulator that is connected to the smart device and is worn on the user's body may be a form of conductive glove . ≪ / RTI >

Hereinafter, the use state and operation state of the wave providing ornaments using the sawtooth wave form according to one embodiment of the present invention will be described.

A user wears a low frequency stimulator on his / her hand, and the user executes a driving application installed in the smart device. When the driving application is executed, the control unit generates a sawtooth wave, that is, an output waveform of a frequency in the form of a sawtooth wave, and outputs an electric stimulation signal.

The output waveform of the sawtooth wave is applied to a low frequency stimulator to output a fine current. In addition, the micro-current applied to the low-frequency stimulator is transferred to the conductive glove so that the micro-current is also applied to the conductive glove. The microcurrent applied to the low frequency stimulator and the conductive glove can be delivered to the user's body, i. E. The user's hand.

At this time, the conductive glove is made of electrically conductive fiber, and a micro current applied from the low frequency stimulator is applied.

Here, the electrically conductive fiber may be a form in which a conductive material obtained by constructing a fine conductive material such as copper or carbon with thin fine lines is mixed with a fiber yarn. Alternatively, it may be a fiber produced by ion-bonding copper and acryl.

As shown in FIG. 6, the smart device having the wave providing function according to another embodiment of the present invention includes a bra, a running shirt for improving the blood flow of the breast, a shoulder, a skin- , Panties for improving blood flow in the genitalia, caps for improving blood flow in the head, and the like.

The smart device having the wave providing function according to an embodiment of the present invention configured as described above is capable of adjusting the frequency minimum current amount of the ELF, SLF, ULF, VLF, LF, MF, HF and VHF bands 1mA of current) can be used to minimize the size of the stimulus generator, and the stimulation generator can be coupled or connected to the smart device to control the drive through the application installed in the smart device.

In an embodiment of the present invention, a smart electric device can transmit a minute electric current to a human body or a micro electric current can be transmitted to every corner of a body by connecting a stimulus generator worn to each part of the body to a smart device, This makes it possible to easily provide a human body with a minute current using this waveform. Thus, one embodiment of the present invention can improve the convenience of electrical therapy.

In addition, an embodiment of the present invention can transmit a micro current to a human body and can exert therapeutic effects such as massage, blood circulation relaxation, stress relaxation, and health promotion effect by minimizing electric stimulation.

The anti-fouling coating layer coated with the anti-fouling coating composition may be formed on the periphery of the low-frequency stimulators 195 and 230 so as to effectively prevent and remove the contaminants from being adhered. The composition for the antifouling coating contains hydrogen peroxide and sodium metasilicate in a molar ratio of 1: 0.01 to 1: 2, and the total content of hydrogen peroxide and sodium metasilicate is 1 to 10% by weight based on the total aqueous solution. In addition, sodium metasilicate or calcium carbonate may be used as the material for improving the coating property of the anti-fouling coating layer, but sodium metasilicate is preferably used. The hydrogen peroxide and sodium metasilicate are preferably in a molar ratio of 1: 0.01 to 1: 2, and when the molar ratio is out of the above range, the coating property of the substrate is lowered or the moisture adsorption on the surface after coating is increased to remove the coating film have.

The hydrogen peroxide and sodium metasilicate are preferably used in an amount of 1 to 10% by weight based on the total weight of the composition. When the amount of the hydrogen peroxide is less than 1% by weight, the applicability of the base material is deteriorated. Precipitation tends to occur.

As a method of applying the composition for anti-fouling coating on a substrate, it is preferable to apply the coating composition by a spray method. The thickness of the final coated film on the low frequency stimulators 195 and 230 is preferably 500 to 2000 angstroms, and more preferably 1000 to 2000 angstroms. When the thickness of the coating film is less than 500 ANGSTROM, there is a problem that it deteriorates in the case of a high-temperature heat treatment. When the thickness is more than 2000 ANGSTROM, crystallization of a coated surface tends to occur.

Further, the composition for antifouling coating can be prepared by adding 0.1 mol of hydrogen peroxide and 0.05 mol of sodium metasilicate to 1000 mL of distilled water, followed by stirring.

In addition, the electrode 231 is coated with a perfume material having a function of treating respiratory diseases and the like, thereby exhibiting an effect of restoring fatigue and improving health of the user.

Functional oil may be mixed with the perfume material, and the mixing ratio thereof is 95 to 97% by weight of perfume, 3 to 5% by weight of functional oil is mixed, the functional oil is 50% by weight of Helichrysum oil, And 50% by weight of Patchouli oil.

Here, the functional oil is preferably mixed with 3 to 5% by weight based on the perfume. If the mixing ratio of the functional oil is less than 3% by weight, the effect is insignificant. If the mixing ratio of the functional oil exceeds 3 to 5% by weight, the function is not greatly improved, but the manufacturing cost is greatly increased.

Among the functional oils, helichrysum oil is one of the main chemical elements such as nerol, geraniol, linalol, and has a good effect on antibacterial, antibacterial, antiseptic, antiallergic and anti-inflammatory.

 Patchouli oil oil is mainly composed of patchouliene, eugenol, carvone, etc. It has excellent effect on sterilization, preservation, anti-inflammation and skin inflammation treatment.

As the functional oil is coated on the surface of the electrode 231, it contributes to recovery of fatigue and health improvement of the user.

On the other hand, the outer surface of the case of the voltage conversion circuit unit 170 may be coated with a discoloring portion that changes color depending on the temperature. The color change part is applied to the surface of the case of the voltage conversion circuit part 170 by separating two or more temperature coloring materials whose color changes when the temperature becomes a predetermined temperature or more into two or more sections according to the temperature change, And a protective film layer is applied on the discolored portion to prevent the discolored portion from being damaged.

Here, the discoloring portion may be formed by applying a temperature discoloring material having a discoloration temperature of not less than 40 DEG C and not less than 60 DEG C, respectively. The color change portion is for detecting a change in temperature of the paint due to a change in color according to the case temperature of the voltage conversion circuit portion 170.

The color change portion may be formed by applying a color change material having a color to the surface of the case of the voltage conversion circuit portion 170 when the color change portion reaches a predetermined temperature or more. In addition, the temperature discoloring substance is generally composed of a microcapsule structure having a size of 1 to 10 탆, and the microcapsules can exhibit a colored and transparent color due to the bonding and separation phenomenon depending on the temperature of the electron donor and the electron acceptor.

In addition, the temperature-changing materials can change color quickly and have various coloring temperatures such as 40 ° C, 60 ° C, 70 ° C, and 80 ° C, and such coloring temperature can be easily adjusted by various methods. Such a temperature-coloring material may be various kinds of temperature-coloring materials based on principles such as molecular rearrangement of an organic compound and spatial rearrangement of an atomic group.

For this purpose, it is preferable that the discoloring unit is formed so as to be divided into two or more sections according to the temperature change by applying two or more temperature-coloring materials having different discoloration temperatures. The temperature-coloring layer preferably uses a temperature-coloring material having a relatively low temperature of the discoloration temperature and a temperature-discoloring material having a relatively high discoloration temperature, more preferably a discoloration temperature of not lower than 40 ° C and not lower than 60 ° C A color change portion can be formed by using a temperature coloring material.

Accordingly, the temperature change of the voltage conversion circuit part 170 can be checked step by step, so that the temperature change of the paint can be sensed. Accordingly, the voltage conversion circuit part 170 can be operated in an optimum state, The voltage conversion circuit portion 170 can be prevented from being damaged in advance.

In addition, the protective film layer is coated on the discolored portion, thereby preventing the discolored portion from being damaged due to external impact, easily confirming discoloration of the discolored portion, and considering the fact that the discolored material is weak to heat, Is preferably used.

It is to be understood that the present invention is not limited to the above-described embodiment, and various modifications and changes may be made without departing from the spirit and scope of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100, 200: smart device 110:
120: transmitting unit 130:
140: control unit 150: display unit
160: memory part 170: voltage conversion circuit part
180: power supply unit 195, 230: low frequency stimulator
190: stimulating portion 201: connection terminal
231: electrode 233: signal line
235: circuit housing 237: connection
239: Connector

Claims (4)

A low frequency stimulator for generating a fine current having a wavelength of a sawtooth wave and transmitting the generated fine current to a human body; And a smart device provided with the low frequency stimulator and provided with an application for driving the low frequency stimulator and controlling the operation of the low frequency stimulator by executing the driving application. The method according to claim 1,
The low-
A controller receiving power from the smart device and outputting a predetermined switching control signal in response to a low frequency stimulation pattern control signal provided from the smart device; And a voltage conversion circuit unit for supplying a high / low voltage low current signal to the stimulating means in response to the switching control signal. And a low frequency stimulator for generating a fine current having a wavelength of a sawtooth wave corresponding to a low frequency stimulation pattern signal of a smart device provided from the connection unit, the low frequency stimulator having a connection unit coupled to a connection terminal of the smart device, At least two or more electrodes for transmitting the generated microcurrent to the human body are provided,
Wherein the smart device is provided with an application for driving the low frequency stimulator and a wave providing function for controlling the operation of the low frequency stimulator by execution of the driving application. The method according to claim 1 or 3,
The driving application
A plurality of low frequency stimulation patterns of ELF, SLF, ULF, VLF, LF, MF, HF and VHF band frequencies are supplied according to a user's selection, and the low frequency stimulation pattern is a pattern of vibration, massage, trembling, Including,
Wherein the smart device is provided with a wave providing function capable of adjusting time or intensity of a low frequency stimulation pattern.

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