KR101872819B1 - Neuromuscular electrical stimulation using self-heating bionic electrode technique - Google Patents

Abstract

The present invention relates to a self-heating type low frequency treatment machine using a bionic electronic heating element. The present invention includes: a mono-species bionic electrode heating element (10) having electrical conductivity; an installation member (20) in which the bionic electrode heating element is installed; a power supply part (30) supplying power to a heat emitting device and a low frequency generating device; the heat emitting device (40) making the electrode heating element emit heat; the low frequency generating device (50) making the electrode heating element output a low frequency current; and a control part (60) controlling the output of the low frequency current and the heat emission of the bionic electrode heating element (10) by controlling power supply. According to the present invention, since the mono-species bionic electrode heating element having electrical conductivity is able to be heated through a self-heating method and also a low frequency current is enabled to be outputted, the present invention is capable of accurately and quickly controlling temperature and maximizing the effects of heating and low frequency treatments through control on heat emission and low frequency current output.

Description

TECHNICAL FIELD [0001] The present invention relates to a direct heating type low-frequency thermal therapy device using a living body electrode heating element,

More particularly, the present invention relates to a direct heating type low-frequency electric therapy apparatus using a living body electrode heating body, and more particularly, to a single type electrode heating body having electric conductivity, The present invention relates to a direct heating type low-frequency heating apparatus using a living body electrode heating body that can maximize the effects of low-frequency heating by making it possible to use the electrode heating body as both a heating treatment and a low-frequency treatment.

Interest in health is increasing day by day, and a variety of devices for health promotion are being developed and distributed.

In particular, a low-frequency thermal therapy device is a device for stimulating the human body by transmitting heat or low-frequency current to a local site using a heating device and a low-frequency generator. The device is used for various purposes such as fatigue recovery and physical therapy, It is widely used in hospitals, clinics and general households.

Meanwhile, in a conventional heating device for a low-frequency electrical therapy apparatus, a heating wire is embedded in a heating pad having a predetermined thickness, which is made of silicon or a non-woven material, in order to transmit heat to a local site. And indirect heat transfer method in which heat is transferred to the local region of the human body.

However, in the case of a general heating line, defects occur frequently due to disconnection or the like, and since the heating of the heating pad heated by the heating line is indirectly applied to the human body, the heating efficiency is low and the power consumption is high.

Further, in the case of the indirect heating method, even if the heating pad surrounding the heating line is overheated by the heating line to shut down the power supply to the heating line in order to lower the temperature, the temperature of the heated heating pad gradually falls, There are disadvantages.

If the temperature of the heating pad is heated to a temperature higher than the user's desired temperature or the user tries to control the temperature during use in the case where the temperature control is not quick and accurate as described above, . ≪ / RTI >

In addition, a conventional low-frequency generator of a low-frequency electric therapy apparatus uses an AC power source to transmit a low-frequency current to a human body.

However, if an AC power source for outputting a low frequency current is supplied to a heat generating pad having a built-in heating wire which is heated by a DC power source, the power supply can not be provided due to the offset of the DC power source and the AC power source.

Therefore, in the conventional low-temperature and low-frequency therapy apparatus, a heating pad for generating heat and a low-frequency electrode for outputting a low-frequency current are separately provided. Generally, the heating pad has a large installation area and a low- .

As a result, the fever is applied to a relatively wide area of the human body, while the low frequency is limited to a very narrow area, so that the effect of low frequency treatment is not high.

In addition, a low-frequency current is not transmitted to a local region of the human body where heat is transmitted by the heat-generating pad, and heat transmission is not performed to a local region of the human body in which a low-

Accordingly, the conventional low-temperature and low-frequency treatment apparatus has a disadvantage that the treatment effect is not so high by performing the warm treatment and the low-frequency treatment at different parts of the human body, instead of simultaneously performing the warm treatment and the low- .

Published Patent Application No. 10-2002-0083100 Published Utility Model Publication No. 20-2015-0001870

In order to solve the above-described problems of the prior art, a direct heating type low-frequency electric therapy device using a bioelectrode heating element of the present invention is a device for heating a single kind of electrode heating body having electric conductivity by a direct heating method, So as to enable accurate and rapid temperature control during the thermal treatment.

In addition, since the electrode heating body of a single kind having electric conductivity enables the output of low frequency electric current for the treatment of low temperature as well as the heating for the heating treatment, the electrode heating body of a single kind can be used for both the thermal treatment and the low frequency treatment The purpose is to make.

In addition, the present invention enables the generation of heat or low-frequency current output or heat generation and the output of low-frequency current through the power supply control of a single electrode heating element having electrical conductivity, So as to be able to maximize the performance of the system.

According to an aspect of the present invention, there is provided a low-temperature,
A single-body bioelectrical electrode heating element (10) having electrical conductivity;
An installation member (20) on which a plurality of the body-electrode heat generating elements (10) are installed;
A power supply unit 30 supplied with external power and supplying power to the heat generator unit 40 and the low frequency generator unit 50;
A heating device unit (40) for supplying DC power to the body electrode heating element (10);
A low frequency generator unit (50) for supplying AC power to the body electrode heating element (10);
A controller (60) for controlling supply of power to the body-electrode heat generating element (10) in the heating device part (40) and the low-frequency generating device part (50); Including,
The body-electrode heating element (10)
The silicon and the carbon powder are mixed in a predetermined ratio to form a predetermined size block,
A pair of connection terminal portions 101 are formed at a predetermined interval on the bottom surface to enable direct heat generation by DC power supply and low frequency current output by AC power supply,
And a light source mounting hole 102 is formed in the center of the infrared LED light source 80,
The mounting member (20)
And an electromyogram sensor (90) for measuring the electromyogram value of the muscle tissue in which warming by the body-electrode heating element (10) and stimulation by a low-frequency current are performed and providing the result to the controller (60)
The control unit (60)
The DC power supply and the AC power supply are alternately repeated at predetermined time intervals to the body-electrode heat generating element 10,
It is possible to randomly select a living body heating element to which a DC power is supplied and a living body heating element to which an AC power is supplied from among a plurality of living body electrode heating elements 10 to generate heat or output of a low- Respectively,
If the measured value of the electromyogram measured during the predetermined period of time during the accumulation of the electromyogram measured by the electromyogram sensor 90 is not more than the pre-stored threshold value, it is notified through the output means that the electromyogram value does not change And outputs the output signal.
The mounting member 20 includes a plurality of the body-electrode heat-generating elements 10 on one surface thereof at a predetermined interval in the lateral and longitudinal directions,

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A printed circuit board 201 for electrically connecting the heating unit 40 and the low frequency generator unit 50 to the living body electrode heating body 10 is built in the mounting member 20.

The controller 60 controls the DC power supply in the heating device 40 and the AC power supply in the low frequency generator 50,

So that the heating of the living body heating element (10) or the output of the low-frequency electric current can be separately controlled by preventing any one of the plurality of living body heating elements (10) composed of a single species from overlapping at the same time.
The controller 60 includes a switching circuit 601 so that only when the AC power is supplied from the low frequency generator 50 to the body heat generator 10 and the polarity of the AC power is changed, , The DC power is supplied from the heating device unit (40) to the body electrode heating body (10), so that the low frequency current output and heat generation of the body electrode heating body (10) can be simultaneously performed.

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A direct heating type low-frequency therapy device using a bioelectrode heating element according to the present invention can supply heat to an electrode heating body having electric conductivity by heating the electrode heating body, It is possible to quickly and accurately control the temperature of the electrode heating element.

Further, by directly supplying power to the electrode heating element to adjust the temperature of the electrode heating element, the efficiency of power use and control stability can be greatly improved.

In addition, since the electrode heating body having electric conductivity can be used to combine the heat generation and the low frequency transmission, low frequency treatment can be performed on the body part where the heat treatment with the electrode heating body is performed, Treatment and low-frequency treatment can be performed at the same time.

In addition, it is possible to selectively apply various operation methods such as heat generation, low-frequency current output, heat generation and low-frequency current combined output to the same human body part, thereby maximizing the effect of the low- .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a configuration according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating body according to the present invention; FIG.
FIG. 2 is a perspective view showing a configuration according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating element of the present invention. FIG.
3 is a perspective view of an electrode heating body according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating body of the present invention.
FIG. 4 is a cross-sectional view of an electrode heating body according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating body of the present invention. FIG.
FIG. 5 is a view illustrating a process of alternately supplying a DC power source and an AC power source to a controller according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating body of the present invention.
6 is a perspective view of an electromyographic sensor according to another embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating element of the present invention.

Hereinafter, in describing a direct heating type low-frequency heating apparatus using a living body electrode heating body of the present invention in detail, the following description is not intended to limit the specific embodiments described in this document to various modifications modifications, equivalents, and / or alternatives are to be understood as being included.

In connection with the description of the drawings, like reference numerals may be used for similar elements, and the terms " first, "" second, ", etc. used in the present invention may refer to various elements in order and / It is used to distinguish one component from another, and is not limited to those components.

For example, 'first part' and 'second part' may represent different parts, regardless of order or importance. For example, without departing from the scope of the invention described in the present invention, the first component can be named as the second component, and similarly, the second component can also be named as the first component.

Furthermore, the terms used in the present invention are used only to describe specific embodiments, and are not intended to limit the scope of other embodiments. The singular expressions may include plural expressions unless the context clearly dictates otherwise.

Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by one of ordinary skill in the art. The general predefined terms used in the present invention can be interpreted in the same or similar meaning as the contextual meanings of the related art, and, unless expressly defined in the present invention, mean ideal or overly formal meanings . It is needless to say that the terms defined in the present invention can not be construed as excluding the embodiments of the present invention.

FIG. 1 is a block diagram showing a configuration according to an embodiment of a direct heating type low-frequency electric therapy apparatus using a living body electrode heating body according to the present invention. FIG. 2 is a schematic view of a direct heating type low- FIG. 3 is a perspective view illustrating an electrode heating body according to an embodiment of a direct heating type low-frequency electric therapy apparatus using the living body electrode heating body of the present invention, and FIG. 4 is a perspective view illustrating a direct heating using the living body- Sectional view of an electrode heating body according to an embodiment of the present invention.

Will be described with reference to Figs. 1 to 4. Fig.

A direct heating type low frequency heating apparatus using a living body electrode heating element of the present invention includes a living body electrode heating body 10, a mounting member 20, a power supply unit 30, a heating unit 40, (50), and a control unit (60).

Hereinafter, each component of the present invention will be described in more detail as follows.

The body electrode heating element 10 is formed in a block shape of a predetermined size by mixing silicon and carbon powder at a predetermined ratio, so that they have electrical conductivity by the mixed carbon powder, so that direct heat generation by direct current power supply, Supply low-frequency current output is enabled.

Therefore, when DC power is supplied to the living body electrode heating body 10, the carbon mixed in the living body heating body 10 acts as an electric resistance, so that the living body heating body 10 is directly heated and heat is generated.

Thus, by heating the body electrode heating body 10 in a state in which the body heating body 10 is in close contact with the skin surface of the human body, heat treatment can be performed according to the direct heating of the body electrode heating body 10.

When the AC power is supplied to the body-electrode heating element 10, a low-frequency electric current is output from the body-electrode heating element 10 due to the electric conductivity of carbon mixed in the body-electrode heating element 10.

Thus, by outputting a low-frequency current in a state in which the body-electrode-exothermic body 10 is in close contact with the skin surface of the human body, low-frequency treatment by the body-electrode exothermic body 10 becomes possible.

The mounting member 20 has a plurality of the body-electrode heat generating elements 10 arranged at predetermined intervals in a lateral direction and a longitudinal direction, and the heating unit 40 and the low- And a printed circuit board (201) for electrically connecting the unit (50) to the body electrode heating body (10).

When installing the body-electrode heating element 10 on the surface of the mounting member 20, it is preferable that a plurality of the body-electrode heating elements 10 are arranged at predetermined intervals in the lateral and longitudinal directions.

The attachment member 20 may be formed in a predetermined size using a nonwoven fabric having flexibility, a fiber material, silicon, synthetic rubber or the like so as to cover a local area of a human body or to be able to adhere to a local site of a human body, Injection molding is preferable.

For example, the mounting member 20 may be formed in a belt shape that can be wound around the torso or waist of a human body, or may be formed in various forms such as a mat shape in which a user sits down, It is possible.

The printed circuit board 201 is installed inside the mounting member 20 and is electrically connected to the body-electrode heating element 10 provided outside the mounting member 20, 20) It is better to prevent exposure to the outside.

When the mounting member 20 is formed of a flexible nonwoven fabric, a fiber material, silicone, synthetic rubber or the like, the printed circuit board 201 mounted inside the mounting member 20 is mounted on the flexible printed circuit board Is preferably used.

It is preferable that the power supply unit 30, the heat generator unit 40, the low frequency generator unit 50, and the controller 60 are both provided in a terminal-type controller 70, But it may be integrally formed with the mounting member 20.

The controller 70 is preferably provided with input means and output means for controlling the operation of the heating device 40 and the low frequency generator device 50. The configuration of the controller 70 is well known, A detailed description thereof will be omitted.

The power supply unit 30 supplies DC power to the heat generator unit 40 and AC power to the low frequency generator unit 50 by receiving external power.

That is, when a single external power is supplied to the power supply unit 30, the external power supply is divided into a DC power supply and an AC power supply through the power supply circuit so that the DC power supply is supplied to the heat generator unit 40, To be supplied to the low frequency generator unit 50.

When the power supply unit 30 supplies the direct current power and the alternating current power to the heating device unit 40 and the low frequency generating device unit 50 as described above, the power supplied to the heating device unit 40 is DC 12V 2A And the power supplied to the low frequency generator unit 50 is AC 4V 12mA.

The heating unit 40 supplies direct current power to the body-electrode heating element 10 so that the living-body electrode heating body 10 directly generates heat.

As described above, the heating of the living body electrode heating body 10 is performed by controlling the voltage supplied to the living body heating body 10 so that carbon mixed with the living body heating body 10 generates heat by acting as an electric resistance. The heating temperature of the body electrode heating body 10 can be controlled in proportion to the size of the living body electrode heating body 10.

Therefore, a voltage control circuit for controlling the temperature of the body-electrode heat-generating element 10 is supplied with a voltage to the body-electrode heat-generating body 10 for a predetermined period of time, And an overheat prevention circuit for automatically shutting off the voltage according to the temperature detected by the temperature sensor installed in the body-electrode heating element (10) or the mounting member (20).

Accordingly, as the direct current power is supplied from the heat generator unit 40 to the body-electrode heat-generating body 10, it is possible to perform thermal treatment using the body-electrode heat-generating body 10 which is in close contact with the body part of the body.

As is well known, hyperthermia treats the temperature around 40 ~ 42 ℃, which is higher than the body temperature of the human body, and activates the immune cells through the action of heat, so that the treatment of various diseases or diseases at the heat- It is clinically known that an improvement effect is exhibited.

On the other hand, when the voltage supplied to the living body electrode heating body 10 is controlled, the temperature of the living body heating body 10 can be controlled quickly and precisely because the temperature of the living body heating body 10 is directly controlled.

That is, since the heat generated by the bio-electrode heating element 10 is generated by the carbon mixed with the bio-electrode heating element 10, the heating is performed by controlling the voltage supplied to the bio-electrode heating element 10, The temperature of the heat generated by the body-electrode heating element 10 can be controlled.

When power is supplied to the body-electrode heating element 10 as described above, the power is supplied to the body-electrode heating element 10 through the supply voltage and current within a voltage and current range allowed for the medical device, The risk of electric shock is excluded.

On the other hand, a pair of connection terminal portions 101 are formed at a predetermined interval on the bottom surface of the body-electrode heat generating element 10 for convenience and accuracy of electrical connection for power supply in supplying power to the body- .

The connection terminal portion 101 preferably has a female thread or inserts a female thread so that a simple and robust electrical connection can be achieved through threading with a male thread made of a metal material.

The low-frequency generator unit 50 supplies AC power to the body-electrode heat-generating body 10 to output a low-frequency electric current from the body-electrode heat-generating body 10.

As described above, the body-electrode heat generating element 10 is formed in a block shape of a predetermined size by mixing silicon and carbon powder at a predetermined ratio, and thus has electrical conductivity by the mixed carbon powder.

Therefore, when the AC power of low frequency band is supplied to the body-electrode heat generating element 10, a low-frequency electric current is outputted from the body-electrode heat-generating body 10 in contact with the human body and transmitted to the human body.

At this time, the low frequency generator unit 50 is provided with a frequency control circuit to adjust the frequency band of low frequency, so that it is possible to control various frequency bands within the 10 to 120 Hz band.

Therefore, the body-electrode heating element 10 can generate not only heat for heat treatment but also low-frequency current output for low-frequency treatment, so that a plurality of the body-electrode heating elements 10 are mounted on the mounting member 20 in the horizontal and vertical directions The plurality of the body-electrode heating elements 10 can be used for both the thermal treatment and the low-frequency treatment.

Thus, the low-frequency treatment can be performed on the same region as the human body region where the hyperthermia treatment is performed by using the plurality of the body-electrode heat generating bodies 10, thereby enabling the hyperthermia therapy and the low-frequency treatment for a wider human body region.

As is well known, low-frequency therapy is performed by applying low-frequency currents of a certain pulse to the human body or modulating the low-frequency pulses so as to gradually increase or decrease, thereby repeating muscle contraction. Thus, the muscles are contracted and relaxed, It is clinically known that treatment and improvement effects are exerted for pain and muscle diseases, neuralgia and inflammatory diseases.

In addition, recently, muscle contraction and relaxation through electrical stimulation have similar effects to muscle movement, thereby enhancing muscle mass, increasing basal and metabolic rate, stimulating directly to adipocytes, and reducing cell size and size It is also said to be effective on dieting.

The control unit 60 controls the heating unit 40 and the low frequency generating unit 50 so that the direct current power and the alternating current power are not simultaneously supplied to the living body heating body 10, It is possible to separately control the heat generation and the output of the low frequency current.

That is, after DC power and AC power are supplied from the power supply unit 30 to the heat generator unit 40 and the low frequency generator unit 50, respectively, the control unit 60 supplies the DC power and the AC power to the body- The DC power is supplied or the AC power is separately supplied so as not to be overlapped at the same time.

When the direct current power is supplied to the living body heating element 10 by the control part 60, the living body heating element 10 generates heat. When AC power is supplied to the living body heating element 10, ) Outputs a low-frequency current without generating heat.

The controller 60 controls the DC power supply in the heating device 40 and the AC power supply in the low frequency generator 50 to be applied to the living body heating element 10 at predetermined time intervals It is also possible to have them repeated alternately.

In addition, the controller 60 may randomly select an electrode heating element to which DC power is supplied among the plurality of bio-electrode heating elements 10.

In addition, the controller 60 may randomly select an electrode heating element to which an AC power is supplied from among the plurality of bio-electrode heating elements 10.

Therefore, the heat generation or the low-frequency current output of the body-electrode heat emission body 10 by the control unit 60 can be controlled in various forms.

A plurality of the body-electrode heating elements 10 may be arranged in the mounting member 20 such that the plurality of the body-electrode heating elements 10 are arranged at predetermined intervals in the lateral and longitudinal directions, Some electrode heating elements generate heat and some electrode heating elements output low-frequency current.

At this time, it is also possible to make the number of electrode heating elements that generate heat and the number of electrode heating elements that output low-frequency current be equal to each other, or both may be larger than the other.

As another example, it is also possible to repeatedly output a low-frequency current for a certain period of time after the heat generation of the entire body-electrode heat generating elements 10 has been completed for a predetermined time.

Thus, it is possible for the fever treatment to repeatedly perform low frequency treatment alternately for the same part of the human body.

As another example, it is also possible to cause a plurality of body-electrode heat generating elements 10 as a whole to output a low-frequency current in various frequency bands without generating heat.

As another example, it is possible that the entire body of the plurality of body-electrode heat generating elements 10 is heated, and a part of the electrode heating elements randomly selected out of the plurality of body-electrode heat generating elements 10 stops generating heat and outputs a low-frequency electric current again.

As another example, when some of the body-electrode heat generating elements 10 randomly selected out of the plurality of body-electrode heat generating elements 10 output a low-frequency current and then stop, and again, some of the body-electrode heat generating elements 10 randomly selected output a low- It is also possible to repeat the process.

Therefore, stimulation is performed according to the low-frequency current output by the body-electrode heat generating body 10 locally at various points with respect to a wide body part, thereby improving the low-frequency treatment effect.

That is, as is well known, when low-frequency current is repeatedly and continuously output to the same local region of the human body in the case of low-frequency treatment, as the nerve or muscle tissue of the human body portion adapts to the low frequency, low frequency treatment due to repeated muscle contraction of the muscle tissue The effect is reduced.

Therefore, as in the embodiment of the present invention, some of the plurality of body-electrode heat generating elements 10 randomly output a low-frequency current and then are stopped randomly. , It is prevented that the low frequency current is repeatedly and continuously outputted to the same local region of the human body, so that the reduction of the low frequency therapeutic effect is prevented.

In addition, since a low-frequency current output is locally and randomly performed over a wide area, it is possible to transmit a stimulation by low-frequency current to a plurality of muscle tissues at a time, thereby simultaneously causing muscle contraction for a plurality of muscles, The effect similar to the muscle exercise used is demonstrated.

For example, various muscles, such as the external radiating muscles, the rectus abdominis muscles, and the internal muscles muscles, which are located in the abdomen of the human body, not only cause contraction and relaxation of a single muscle during contraction of the abdomen but contraction and relaxation of multiple muscles located in the abdomen at the same time.

However, when a low-frequency current output is limitedly applied to a local region as in the conventional low-frequency therapy apparatus, it is difficult to stimulate a large number of muscles, such as the abdomen, by a low-frequency current at a time.

On the other hand, in the direct heating type low-frequency heating apparatus using the living body electrode heating element of the present invention, a plurality of the living body heating elements 10 are arranged on the mounting member 20 at predetermined intervals in the lateral and longitudinal directions, All of the heating elements 10 can transmit electrical stimulation to a plurality of muscles at the same time as it is possible to transmit electrical stimulation to a human body through a low frequency current output.

Accordingly, the present invention can enhance the muscle mass, increase the base and metabolic rate, and stimulate the fat cells directly, thereby reducing the number of cells and reducing the size, thereby greatly contributing to the diet. do.

FIG. 5 is a view illustrating a process of alternately supplying a DC power source and an AC power source to the controller according to an embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating body of the present invention.

Will be described with reference to FIG.

The control unit 60 limits the amount of the AC power supplied to the living body heating unit 10 from the heating device unit 40 only when the AC power is supplied from the low frequency generating unit 50 to the living body heating unit 10, The direct current power is supplied to the living body electrode heating body 10 so that the low frequency current output and heat generation of the living body electrode heating body 10 can be simultaneously performed.

In the case of a conventional warm / low-frequency therapy device, when a DC power source and an AC power source are simultaneously supplied to a single medium, the power supply is not performed due to the cancellation of the DC power source and the AC power source. Respectively.

However, the control unit 60 of the present invention is provided with the switching circuit 601 to control the supply of power to the body-electrode heat generating element 10, so that when the AC power for the low-frequency current output is supplied, A DC power supply for the DC power supply can be supplied.

That is, the polarity of the alternating current power source is changed repeatedly at a constant time, and the change of the polarity of 60 times per second is called a frequency of 60 Hz.

In the low frequency generator unit 50 of the present invention, a frequency control circuit is provided to freely adjust the frequency band within 10 to 120 Hz.

Therefore, the controller 60 supplies DC power to the bioelectrical heating element 10 instantaneously at the time when the polarity changes to "0" having no polarity in the course of supplying the AC power to the bioelectrode heating element 10 So that the power supplied to the body-electrode heating element 10 in the heating unit 40 is switched and controlled by using the switching circuit 601.

While the supply of the AC power to the body-electrode heating body 10 is continued by the controller 60, the DC power is supplied to the body-electrode heating body 10 (corresponding to the frequency of the AC power) , The living body electrode heating body 10 is supplied with the alternating current power and outputs the low frequency current so that the heat is generated by the supply of the direct current power.

As described above, when heat generation and low-frequency output are performed simultaneously for the single body-electrode-electrode heating element 10, the effects of the hyperthermia treatment and the low-frequency treatment are doubled.

In other words, the limit of known hyperthermia treatment is that the effect of hyperthermia treatment is limited because the deep tissue of the skin is not transmitted.

As described above, the body-electrode heating element 10 of the present invention can generate heat and a low-frequency current output simultaneously from a single living body electrode heating body 10, Shrinkage occurs simultaneously.

Therefore, as the circulation of the blood, the lymphatic fluid, and the tissue fluid is increased locally, the space of the skin and muscles is locally expanded in the region where the heat is transmitted by the body-electrode heating element 10, The delivery is more deeply transferred from the skin surface to the inside of the skin tissue, thereby doubling the effect of the hyperthermia treatment.

The body electrode heating body 10 may further include a red infrared LED light source 80 for medical use.

That is, a light source installation hole 102 is formed at the center of the body-electrode heating element 10 to embed and install a red-based medical infrared LED light source 80 having a wavelength band effective for skin treatment, The medical treatment using the medical infrared LED light source 80 can be performed in parallel with the thermal therapy and the low frequency treatment.

As is well known, phototherapy using various artificial light sources such as a laser, a fluorescent lamp, a UV lamp, and an LED is used as a light therapy, and the light energy is chemically, Kinetic or thermal energy.

Most importantly, light is absorbed by elements or molecules in the cell. It is therefore important that the light of a particular wavelength is efficiently absorbed into a particular chromophore within the cell.

Therefore, in order to improve the effect of light therapy for treating skin diseases, the medical infrared LED light source 80 of the present invention preferably uses a red infrared LED light source 80 for medical use.

The red-based near-infrared rays are effective not only in reducing pains, inflammation and edema but also in shortening the period of trauma healing in the deep region and effective in preventing cell injury in wound areas It is known.

Particularly, the light of the infrared infrared LED light source 80 penetrates into the epidermal layer of the skin, so that acne treatment, cellulite removal, skin elasticity improvement, and skin cell regeneration are exerted.

In addition, the light of the red infrared LED light source 80 penetrates through the epithelial tissues of the skin and penetrates into the dermis, thereby causing cellular turnover, superficial circulation, anti-inflammatoryemission), and at the same time, the temperature of the cells is raised to increase circulation of blood, lymph, and tissue fluid, thereby inducing pain relief.

Therefore, the effect of the thermal therapy and the low-frequency treatment is doubled by the combination of the thermal treatment with the bioelectrode heating element 10 of the present invention, the low frequency treatment, and the light treatment using the infrared LED light source 80 for medical treatment.

FIG. 6 is a perspective view of an electromyogram sensor according to another embodiment of a direct heating type low-frequency heating apparatus using a living body electrode heating element of the present invention. FIG.

Will be described with reference to FIG.

The mounting member 20 further includes an electromyogram sensor 90 for measuring the electromyogram value of the muscle tissue in which warming by the body-electrode heat generating element 10 and stimulation by a low-frequency current are performed and providing the measured value to the controller 60 .

The electromyogram is a measure of the activity potential of the muscle. By analyzing the EMG value of the muscle, not only can the muscle state such as the muscle contraction degree and the degree of tension be grasped, but also the electromyogram value is analyzed by a certain time unit , Muscular fatigue, motor performance, and abnormal motor function.

As mentioned above, EMG is useful for diagnosing functional abnormalities of muscles. Especially, it is the most common musculoskeletal disease, repetitive muscle strain due to repeated muscle use, Work related Musculoskeletal Disorder, Myofascial Pain Syndrome, Chronic Fatigue & Immune Dysfunction Syndrome, which is painful at a specific muscle site called Trigger Point, ), Fibromyalgia (Fibromyalgia) and diagnosis and rehabilitation training is known to have high clinical value of EMG.

Therefore, the electromyogram measured through the electromyogram sensor 90 is clinically useful through quantitative analysis. The well-known quantitative electromyography method includes a root mean square (RMS) analysis, a power spectrum, a median frequency , RMS-probability distribution analysis, RMS cross-correlation analysis, wavelet analysis, principal component analysis, nonlinear dynamics analysis, high-order statistical analysis, and Laplacian mapping analysis.

In particular, the RMS is capable of analyzing muscle contraction or muscle tension, and the median frequency is capable of analyzing muscular fatigue, and the RMS correlation function (cross-correlation) between muscular regions is capable of analyzing muscle contraction timing.

The electromyogram sensor 90 is installed at least one position between the body-electrode heat generating elements 10 provided on the attachment member 20 so that heat treatment by the body-electrode heat generating body 10 and local treatment of the body where low- And provides the EMG value to the control unit 60. [0033] FIG.

The controller 60 controls the operation of the electromyogram sensor 50 or the electromyogram sensor 60 while the heat treatment or the low frequency treatment is performed alone or in parallel with the local region of the human body in accordance with the power supply including the body- And analyzes the electromyogram value provided by the controller 90 through an algorithm based on an EMG method previously stored in the controller 60.

At this time, the electromyogram measured by the electromyogram sensor 90 is cumulatively accumulated in the controller 60, and the final measured value is compared with a normal electromyogram reference value previously stored in the controller 60, Through the output means of the controller (70).

Therefore, the user can directly recognize the therapeutic effect or the state change on the affected part where the hyperthermia treatment or the low frequency treatment is performed, and thus the reliability of the hyperthermia treatment and the low frequency treatment is greatly improved.

When the final measured value is compared with the reference value, the controller 60 notifies the controller 70 of the fact that the state of the local region of the human body to be treated is normalized, Lt; / RTI >

In addition, if the electromyogram measured during the predetermined period of time during the accumulation of the electromyogram measured by the electromyogram sensor 90 in the controller 60 is not greater than the pre-stored threshold value, the controller 70 Through the output means of the control unit.

Therefore, the user can recognize that there is no additional state improvement effect of the affected part where the hyperthermia treatment or the low frequency treatment is performed.

Combinations of each block of the block diagrams appended hereto may be performed by program instructions. These program instructions may be embedded in a processor of a general purpose digital controller or other programmable data processing equipment so that the instructions performed through these processors produce means for performing the functions described in each block of the block diagram.

These program instructions may be stored in a digital controller-usable or digital controller readable memory capable of directing a computer or other programmable data processing equipment to implement the function in a particular manner, It is also possible for the instructions stored in the readable memory to produce an article of manufacture containing instruction means for performing the functions described in each block of the block diagram.

It is also possible that the program instructions may be mounted on a digital controller or other programmable data processing equipment so that a series of operating steps are performed on a digital controller or other programmable data processing equipment to create a process running on the digital controller, Or other programmable data processing equipment may also provide steps for performing the functions described in each block of the block diagram.

In addition, each block may represent a module, segment, or portion of code that includes one or more executable instructions for executing the specified logical function (s).

It goes without saying that the functions mentioned in the blocks may occur out of order in some alternative embodiments. For example, two blocks shown in succession may actually be executed substantially concurrently, or the blocks may sometimes be performed in reverse order according to the corresponding function.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. While the present invention has been described in connection with the preferred embodiments thereof with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art.

10: electrode heating element 101: connection terminal portion
102: light source mounting hole 20: mounting member
30: power supply part 40: heating device part
50: Low frequency generator unit 60:
70: Controller 80: medical infrared LED light source
90: EMG sensor

Claims (11)

A single-body bioelectrical electrode heating element (10) having electrical conductivity;
An installation member (20) on which a plurality of the body-electrode heat generating elements (10) are installed;
A power supply unit 30 supplied with external power and supplying power to the heat generator unit 40 and the low frequency generator unit 50;
A heating device unit (40) for supplying DC power to the body electrode heating element (10);
A low frequency generator unit (50) for supplying AC power to the body electrode heating element (10);
A controller (60) for controlling supply of power to the body-electrode heat generating element (10) in the heating device part (40) and the low-frequency generating device part (50); Including,
The body-electrode heating element (10)
The silicon and the carbon powder are mixed in a predetermined ratio to form a predetermined size block,
A pair of connection terminal portions 101 are formed at a predetermined interval on the bottom surface to enable direct heat generation by DC power supply and low frequency current output by AC power supply,
And a light source mounting hole 102 is formed in the center of the infrared LED light source 80,
The mounting member (20)
And an electromyogram sensor (90) for measuring the electromyogram value of the muscle tissue in which warming by the body-electrode heating element (10) and stimulation by a low-frequency current are performed and providing the result to the controller (60)
The control unit (60)
The DC power supply and the AC power supply are alternately repeated at predetermined time intervals to the body-electrode heat generating element 10,
It is possible to randomly select a living body heating element to which a DC power is supplied and a living body heating element to which an AC power is supplied from among a plurality of living body electrode heating elements 10 to generate heat or output of a low- Respectively,
If the measured value of the electromyogram measured during the predetermined period of time during the accumulation of the electromyogram measured by the electromyogram sensor 90 is not more than the pre-stored threshold value, it is notified through the output means that the electromyogram value does not change Wherein the bioelectrode heating element is a direct heating type low temperature electric therapy device using a bioelectrode heating element. delete The method according to claim 1,
The mounting member (20)
A plurality of the body-electrode heat-generating bodies 10 are provided at predetermined intervals in the lateral and longitudinal directions,
A printed circuit board (201) for electrically connecting the heating unit (40) and the low frequency generator unit (50) to the body electrode heating body (10) is built in the mounting member (20) A direct heating type low temperature therapy device using an electrode heating body. The method according to claim 1,
The control unit (60)
The direct current power supply in the heating device unit 40 and the alternating current power supply in the low frequency generator unit 50,
Electrode heating body (10) so that the heating of the body-electrode heating element (10) or the output of a low-frequency current can be separately controlled so as not to be superposed simultaneously on any one of the plurality of electrode heating elements A Low - Frequency Therapy System Using Direct Heating. delete delete delete The method according to claim 1,
The control unit (60)
And a switching circuit 601. The heating circuit unit 40 is provided with a switching circuit 601 so that only the moment when the polarity of the AC power is changed while the AC power is supplied from the low frequency generator 50 to the body- Wherein the direct current power is supplied to the living body electrode heating body (10) so that the low frequency current output and heat generation of the living body body heating body (10) are simultaneously performed. delete delete delete

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