KR20100129702A - Brace for micro current stimulation - Google Patents

Abstract

PURPOSE: A protector for micro current stimulation is provided, which is effective for prevention and treatment of osteoporosis patients. CONSTITUTION: A protector for micro current stimulation comprises: a liner(11) and an outer cover(12) which is formed into a band shape and is made of non-conducting substance; a plurality of stimulation members(15) which are attached to the inner side of the liner and are made of conductive material; and a micro current generator which is electrically connected to a plurality of stimulation plates and supplies micro current to the stimulation plates.

Description

Subband for microcurrent stimulation {BRACE FOR MICRO CURRENT STIMULATION}

The present invention relates to a wrist worn on the joints such as wrists, ankles, wrists, knees, etc. In particular, by stimulating by delivering a microcurrent to the joints is very effective in the treatment or prevention of arthritis patients, osteoporosis patients in everyday life. Rather, the present invention relates to a microcurrent stimulation band that can greatly contribute to the growth of children or adolescents through the growth of microcurrents on the growth plates of the knees, ankles and soles.

As is well known, a wrist and the like have been worn on the joints of the human body such as wrists, ankles, wrists, knees, and the like to protect the joints. In particular, in the case of arthritis patients, osteoporosis patients, and the like to wear a belt to protect the joints. As described above, the conventional wristband focuses on the joint protection functions of the wrist, ankle, wrist, knee, and the like.

Microcurrent during electrostimulation is also called "biological stimulation" or "bioengineering" because of its ability to stimulate cell physiology and growth. Microcurrent has an excellent effect on wound healing, and one of the mechanisms of wound healing is hypothesized to facilitate intracellular metabolism and stimulate ATP production by energizing the body with the same microcurrent. Since microcurrents have been found to directly affect local microcirculation to soothe inflammation, many studies have been conducted and the high effects of microcurrents on the treatment and wound healing of Achilles tendonitis have been reported in several papers. In addition, since the microcurrent is carried out in a range below the sensory sense almost no current has the advantage that can be treated without the discomfort caused by the current appearing in the previous electrotherapy.

Such microcurrent stimulation therapy can be used for the control of pain in various musculoskeletal disorders and neurological diseases such as myofascial pain syndrome, tennis elbow, shoulder adhesion adhesive arthritis, arthritis, as well as peripheral neuropathy such as diabetic neuropathy and disc disease. As a mechanism of microcurrent stimulation treatment, the rate of nerve conduction of Aδ-fiber, which delivers sensory nerves, is faster than that of C-fber, which controls pain. Promotes the secretion of the back has the effect of lowering the pain threshold.

The present invention has been made in view of the above, it is excellent in the treatment, prevention and treatment of arthritis patients, osteoporosis patients, growth of children, adolescents, etc. by delivering a microcurrent to the wrist, ankle, wrist, knee of the human body An object of the present invention is to provide a subband for microcurrent stimulation that can exert an effect.

The present invention for achieving the above object,

Endothelial and outer shell formed in a band shape, made of a non-conductive material;

A plurality of magnetic pole members attached to the inner surface of the endothelium and made of a conductive material;

A microcurrent generator electrically connected to the plurality of magnetic pole plates to supply a microcurrent to the magnetic pole plates; And

Includes; the planar heating element interposed between the endothelial and the outer shell,

The planar heating element is composed of a heating element coated with a heating layer made of a polymer mineral containing carbon, characterized in that the planar heating element is connected to a temperature control unit.

The magnetic pole member is formed of any one of a conductive rubber, a conductive metal, a conductive fabric, characterized in that attached to the inner surface of the endothelium.

At least one connection patch is connected to the microcurrent generator through a wire, and the connection patch is provided with an auxiliary magnetic pole plate.

The microcurrent generator,

Generating a first control signal for generating a microcurrent having a positive phase, a second control signal for generating a microcurrent having a negative phase, and a third control signal for boosting a power supply voltage to control the microcurrent generation And checking the level of the microcurrent supplied to the human body through the microcurrent generator and controlling the third control signal to change the voltage level of the boosted voltage when the level is not a predetermined level. Control unit for controlling the;

A booster boosting a power supply voltage to a boosted voltage of a predetermined level in response to the third control signal of the control unit; And

On the basis of the boosted voltage boosted by the booster, a microcurrent having a desired level is generated and supplied to a specific part of the human body through connection terminals connected to the human body, and when the first control signal is input, And a microcurrent output unit for supplying the microcurrent having a phase and supplying the microcurrent having a negative phase when the second control signal is input.

The microcurrent output unit includes at least one voltage distribution circuit and a plurality of switching elements, and each of the plurality of switching elements performs a switching operation in response to the first control signal or the second control signal. .

The microcurrent output unit generates and supplies a supply level confirmation signal for confirming a human supply level of the microcurrent supplied to the human body, and provides the control unit, and the control unit generates a boosted voltage in response to the supply level confirmation signal. Characterized by controlling the level.

The first control signal and the second control signal is a pulse signal having a predetermined period and a certain duty ratio, characterized in that the first control signal and the second control signal has a predetermined phase difference.

The control unit checks whether the human body connection terminals are actually connected to the human body through the supply level confirmation signal, and controls whether or not a microcurrent is generated.

The present invention as described above, by delivering a microcurrent to the wrist, ankle, wrist, knee of the human body to implement the effects of cartilage production, bone growth, bone density, etc. can contribute to the treatment or prevention of arthritis patients, osteoporosis patients, etc. have.

In addition, the present invention has the advantage that can exert an excellent effect on the growth of children or adolescents of the growth phase through the micro-current stimulation on the growth plate of the knee, ankle, sole.

1 is a perspective view showing a subband for microcurrent stimulation according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA of FIG. 2.
3 is a block diagram illustrating a microcurrent generator applied to the microcurrent stimulus band of the present invention.
4 is a circuit diagram illustrating an example of the microcurrent generator of FIG. 3.
5 is an operation timing diagram of FIG. 4,
6 illustrates another embodiment of the booster of FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate a band for microcurrent stimulation according to an embodiment of the present invention.

As shown, the microcurrent stimulus band of the present invention is formed in a band shape so as to be easily worn on the joint portion of the wrist, wrist, ankle, knee, etc., both ends of the band is provided with a detachable portion 16, The detachable part 16 is composed of a Velcro fastener, a ring, a buckle, and the like, and can be easily worn on the joint part of the human body.

The band of the present invention is composed of the inner shell 11 and the outer shell 12, the inner shell 11 and the outer shell 12 is composed of a non-conductive material fibers or synthetic resin.

The outer shell 12 is made of a general fiber material, and the inner skin 11 is a part which is in direct contact with the skin, and thus is made of a material harmless to the skin, such as a cotton fabric.

A plurality of magnetic pole members 15 are disposed on the inner surface of the endothelium 11, and each magnetic pole member 15 may be disposed at a position corresponding to the acupuncture points of the knee, ankle, wrist, and wrist portion or other positions.

The magnetic pole member 15 according to the exemplary embodiment may be formed of a conductor such as conductive rubber or a conductive metal, and the magnetic pole member 15 of a conductive material may be attached to an inner surface of the inner shell 11 through an adhesive or the like. The microcurrent is transmitted to the wrist, the wrist, the ankle, the knee, and the like through the stimulus member 15, thereby facilitating the metabolism of cells, thereby exhibiting an excellent effect on relieving joint pain. In particular, according to the present invention, when a stimulus by microcurrent is transmitted to the growth plate and the growth point of the knee, the ankle, the sole of the foot, the calf bone, the tibia, the thigh bone, etc. can be grown, thereby making a long leg and In addition, the knee and lower body strength can be increased.

On the other hand, the magnetic pole member 15 according to another embodiment is composed of a conductive fabric woven or knitted good conductive yarns such as gold yarn, silver, verbs, etc., the magnetic pole member 15 of the conductive fabric is endothelial through a sewing process It can be attached to the inner side of (11).

The microcurrent generator 150 is electrically connected to the magnetic pole member 15 so that the microcurrent generated by the microcurrent generator 150 is transmitted to the human body through the magnetic pole member 15.

In addition, a planar heating element 14 may be interposed between the endothelium 11 and the outer skin 12, and the heat generation function of the planar heating element 14 facilitates blood circulation to help health.

The planar heating element 14 may be connected to the power supply side of the microcurrent generator 150 or to a separate external power supply side. Accordingly, when power is supplied to the planar heating element 14, the planar heating element 14 is operated to heat, and thus, the blood circulation of the worn portion may be smoothly performed by the heat of the planar heating element 14. In addition, a temperature control unit 16 is connected to the planar heating element 14, the heat generating temperature of the planar heating element 14 can be appropriately adjusted by the temperature adjusting unit 16.

On the other hand, the planar heating element 14 is composed of a heating element coated with a heat generating layer 14a made of a polymer mineral containing carbon on one surface thereof, thereby reducing the power consumption and the number of charges of the battery can be reduced. In addition, there is no damage even when washing, there is an advantage that it is easy to use semi-permanent. In addition, a large amount of anions to far infrared rays are emitted by the heat generating layer 14a containing carbon, which is beneficial to health.

 In addition, in the present invention, the microcurrent generator 150 has one or more connection patches 17 connected to each other through the wires 17a and positioned outside the axle, and the connection patch 17 is provided with an auxiliary magnetic pole member 18. The connecting patch 17 may be used by attaching the band of the present invention to a joint (wrist, wrist, ankle, knee, etc.) and then attached to the acupuncture point adjacent to the worn position.

The operation of the present invention as described above will be described in detail as follows.

It is known that a microcurrent of about 0.06 mA flows in the human body, and the strength of the microcurrent varies depending on the state of health. In general, a phenomenon in which the amount of microcurrent flows in a poor state of health is known clinically.

Thus, by stimulating the microcurrent from the outside having a size enough to stimulate the human body may contribute to the internal balance. In addition, although there is a slight difference depending on the sense level of the body, it is generally known that a current of about 1 mA can be sufficiently perceived, and a long time energization is known to be undesirable.

Therefore, if the size of the microcurrent is less than 1 μs to a few hundreds of amps, it may be suitable for the massage or treatment, and it may be desirable that the microcurrent flows intermittently for a certain period of time instead of continuous flow to give electric stimulation. .

According to the present invention, the microcurrent generated by the microcurrent generator 150 is transmitted to the stimulus member 15, so that the stimulus member 15 applies electrical stimulation to acupuncture points or other parts of joints such as wrists, wrists, ankles, knees, and the like. Can be done.

In addition, the present invention can contribute to the health promotion of the human body by smoothing the blood circulation of the wrist, wrist, ankle, knee and the like by the heat function of the planar heating element (14).

 In addition, the plurality of magnetic pole members 15 according to the present invention may be divided into a negative electrode plate and a positive electrode plate, and may further increase the effect of the electrical stimulation by separately transmitting the negative current and the positive electrode current to the skin of the human body. .

3 to 6 show one form of the microcurrent generator 150 applied to the present invention.

Figure 3 is a block diagram showing a microcurrent generator according to the present invention. As shown, the microcurrent generator 150 of the present invention includes a control unit 310, a boosting unit 320, and a microcurrent output unit 330.

The control unit 310 is a first control signal (S1) for generating a fine current having a positive phase, a second control signal (S2) for generating a fine current having a negative phase, and for boosting the power supply voltage The third control signal S3 is generated to control the generation of the microcurrent. The control unit 310 checks the level of the microcurrent supplied to the human body through the microcurrent generator 150 and controls the third control signal S3 to adjust the level of the boosted voltage when the level is not a predetermined level. By varying, the human body supply level of the microcurrent is controlled.

The control unit 310 may include a control chip having a CPU to generate the first to third control signals S1, S2, and S3.

The booster 320 boosts the power voltages Vdd and Vcc to a boosted voltage of a predetermined level in response to the third control signal S3 of the control unit 310 to the microcurrent output unit 330. Supply.

The booster circuit constituting the booster unit 320 includes a booster circuit of a DC-DC converter type using a back electromotive force of an inductor, a charge pump circuit using a capacitor, and to those skilled in the art. Various well known boost circuits can be used.

The microcurrent output unit 330 generates a microcurrent of a desired level based on the boosted voltage boosted by the booster 320 and supplies the microcurrent to the specific site of the human body through contact terminals in contact with the human body. .

The microcurrent output unit 330 supplies the microcurrent having a positive phase when the first control signal S1 is input, and a negative phase when the second control signal S2 is input. Supply the microcurrent having a.

Here, the microcurrent is a current level of 0 to 1000 mA (not including 0) and refers to the micro current in microamps. The microcurrent output unit 330 is generated by selecting any current level determined to have the highest therapeutic effect or massage effect among the current levels of 0 to 1000 mA (not including 0). For example, a microcurrent of 0 to 300 mA or a micro current of 100 to 150 mA can be output.

In order to generate the microcurrent, the microcurrent output unit 330 includes at least one voltage distribution circuit and a plurality of switching elements, and each of the plurality of switching elements may include the first control signal S1 or the first control element. The switching operation may be performed in response to the two control signal S2.

The microcurrent can be varied in response to the skin resistance of the human body used to make the level of the microcurrent actually supplied to the human body constant.

To this end, the microcurrent output unit 330 generates a supply level confirmation signal for confirming the human body supply level of the microcurrent supplied to the human body and provides it to the control unit 310, and the control unit 310 provides the In response to the supply level confirmation signal, the level of the boosted voltage of the booster 320 is controlled.

Here, the supply level confirmation signal provides a function for confirming whether the condition for supplying the microcurrent is actually made in contact with the human body in addition to the function for confirming the level of the microcurrent actually supplied to the human body.

4 is a circuit diagram illustrating an example of implementation of the microcurrent generator of FIG. 3.

As shown, the control unit 310a is a control chip (for example, PIC16F716) (U2), resistor (R4), capacitor (C4), power (Vcc), LED to determine whether the power supply ( Including the D2) has a wiring structure as shown in FIG. The control chip U2 may be a generator of a control signal having various kinds of frequencies.

As illustrated in FIG. 3, the control unit 310a may include a first control signal S1 for generating a microcurrent having a positive phase, a second control signal S2 for generating a microcurrent having a negative phase, And generating a third control signal S3 for boosting the power voltage to control the microcurrent generation.

In addition, the control unit 310a receives the supply level confirmation signal MC for confirming the human body supply level of the microcurrent supplied to the human body provided by the microcurrent output unit 330a to receive the booster 320a. The level of the boosted voltage VC can be controlled. The level control of the boosted voltage VC is possible through the third control signal.

Although the control unit 310a checks the human body supply level of the microcurrent through the supply level confirmation signal MC, it is also possible to check whether the human body contact terminals P1 and P2 actually contact the human body. . This is because it is possible to determine that the human body contact terminals P1 and P2 are in contact with the human body if the supply level confirmation signal MC is within a range corresponding to the skin resistance because the range of the human body's skin resistance is determined. Here, the body contact terminals P1 and P2 correspond to the magnetic pole member 15.

Therefore, when power is supplied, the control unit 310a first checks whether the human body contact terminals P1 and P2 are in contact with the human body through the supply level confirmation signal MC, and whether a microcurrent is generated. It is decided. That is, when it is confirmed that the human body is contacted through the supply level check signal MC, the microcurrent is generated through the microcurrent generator, and then the function of confirming the actual human supply level of the microcurrent is performed.

Since the control unit 310a has to be movable and portable, the power supply voltage may be configured to be supplied through a battery.

The booster 320a may include a switching element Q7, which is repeatedly switched by the third control signal S3 generated by the control unit 310a, an inductor L1, rectification and ripple prevention, and boost voltage. A diode D1 for storage, capacitors C1 and C2, and a resistor R10 have a wiring structure as shown in FIG. 4. In this case, a transistor is used as the switching element Q7, but various switching elements including a MOSFET may be used.

As shown in FIG. 6, the boosting unit 320a may be configured through a boost circuit of a DC-DC converter type having the boost stage 10 formed in multiple stages, and may include various boost circuits such as a boosting circuit. It is possible to implement

 The microcurrent output unit 330a includes a plurality of voltage dividers using a plurality of resistors R1, R6, R2, R7, R8, and R9 and a plurality of switching elements Q1, Q2, Q3, Q4, Q5, and Q6. ) To output a microcurrent to the human body contact terminals (P1, P2). The plurality of switching elements Q1, Q2, Q3, Q4, Q5, and Q6 use transistors, but various switching elements including MOSFETs may be applied.

Some switching elements Q6 and Q3 of the switching elements Q1, Q2, Q3, Q4, Q5 and Q6 are controlled by the first control signal S1, and some switching elements Q5 and Q4 are controlled. Is controlled by the second control signal S2, and the remaining switching elements Q1 and Q2 are controlled by the voltage of the first node n1, that is, the boosted voltage VC.

The human body contact terminals P1 and P2 are mounted on specific parts of the human body (sites requiring treatment or massage), and the second human body contacts the microcurrent applied through the first human contact terminal P1 through the human body. It may be configured to return to the terminal (P2), or to allow the micro-current applied through the second human contact terminal (P2) to pass through the human body to return to the first human contact terminal (P1).

5 is a timing diagram of the control signal and the fine current of FIG. 4.

Hereinafter, the operation of the microcurrent generator of FIG. 4 will be described with reference to the timing diagram of FIG. 5.

First, the microcurrent generator 150 operates while the human body contact terminals P1 and P2 of the microcurrent generator 330a of the microcurrent generator 150 are mounted on a specific part of the human body.

When power is supplied through a battery, the control unit 310a generates a signal for confirming whether the human body is in contact with the microcurrent output unit 330a or the third control signal S3 for generating a general microcurrent. In addition, the supply level confirmation signal MC is received to check whether the human body contact terminals P1 and P2 actually touch the human body.

This is because when the level of the supply level confirmation signal MC is positioned within a predetermined range in consideration of the skin resistance of a general human body, it is possible to determine that the human body is in contact with the human body.

Thereafter, the control unit 110a supplies the third control signal S3 for generating a microcurrent to the boosting unit 320a. The third control signal S3 is a control signal whose width and period are adjusted for boosting.

When power is supplied through a battery, the control unit 310a supplies the third control signal S3 to the boosting unit 320a. The third control signal S3 is a control signal whose width and period are adjusted for boosting.

When the third control signal S3 is applied, the switching element Q7 of the boosting unit 320a is turned on / off in response to the third control signal S3.

When the switching element Q7 is turned on, the current of the inductor L1 starts to increase, and the diode D1 is turned off because the bias is applied in the reverse direction, thus the inductor The voltage (L1) becomes equal to the power supply voltages Vcc and Vdd. When the switching device Q7 is turned off by the third control signal S3 again, the current of the inductor L1 starts to decrease, and accordingly, the voltage of the inductor L1 The polarity is changed to merge with the power supply voltage. This voltage is stored in capacitor C1.

In this case, a forward bias is applied to the diode D2, and the capacitor C2 stores a voltage output through the diode D2, and the voltage of the output voltage, that is, the boosted voltage VC, is on. Eliminate pulsations (ripples).

When the next switching operation is performed, a voltage corresponding to twice the voltage stored in the capacitor C1 is stored in the capacitor C2. When a plurality of switching operations are performed in this manner, the first node n1 ) Generates a boosted voltage VC several times to several ten times higher than the power supply voltages Vcc and Vdd. For example, assuming that the power supply voltage is 3V, it is possible to obtain a voltage of 30V. Of course, it is also possible to generate higher levels of voltage.

That is, when the switching device Q7 repeatedly performs the on / off operation according to the width and the period of the third control signal S3 of the control unit 310a, the boosted voltage VC has a desired level. .

When the boosted voltage VC reaches a desired level, the control unit 310a generates a first control signal S1 and a second control signal S2. The first control signal S1 and the second control signal S2 may be generated at the same time as the supply of the power supply voltage of the control unit 310a, but it does not mean that the boosted voltage VC reaches a desired level. Therefore, it is assumed here that it occurs when the boosted voltage VC reaches a desired level.

The first control signal S1 is for generating a micro current having a positive phase, and the second control signal S2 is for generating a micro current having a negative phase.

When a microcurrent having a positive phase and a negative phase is generated and supplied to the human body, the treatment and massage effects are known to be superior to those of the microcurrent having only a positive phase.

The first control signal S1 is shown in FIG. 5. It may have a waveform structure of the pulse (pulse) having a certain period and a certain duty ratio (duty ratio). For example, it may have a waveform structure having a period of 1 second and a constant voltage level for a time of 150 ms, and a voltage level of 0 for the remaining time.

However, this is just one example. In consideration of the effective aspect of treatment or massage, the period or duty ratio may be changed by a unit of time, and the period or duty ratio may have a different waveform structure.

The second control signal S2 may have a waveform structure in the form of a pulse having a certain period and a constant duty ratio in a form having a predetermined phase difference from the first control signal S1. The second control signal S2 has the same shape except that it has a predetermined phase difference from the first control signal S1.

Here, the second control signal S2 should have a voltage level of 0 in a time interval t1 in which the first control signal S1 has a constant voltage level, and the first control signal S1 has a voltage of 0. In some sections of the time section T-t1 having the level, the waveform structure has a constant voltage level.

That is, the pulse of the first control signal S1 and the pulse of the second control signal S2 are generated so as not to overlap. That is, the timing at which the switching elements Q6 and Q3 are turned on by the first control signal S1 and the timing at which the switching elements Q5 and Q4 are turned on by the second control signal S2 should be different. Immediately after the switching elements Q6 and Q3 are turned on by the first control signal S1 and turned off again, the switching elements Q5 and Q4 are turned on by the second control signal S2. The switching elements Q6 and Q3 are turned on by the first control signal S1 and then turned off again, and after a predetermined time, the switching elements Q5 and Q4 are turned on by the second control signal S2. It is also possible to turn on. This is possible by controlling the timing of the pulse generation of the second control signal S2, and may be determined differently as necessary in consideration of treatment or massage effects.

When the boosted voltage VC reaches a predetermined level, the microcurrent output unit 330a turns on the switching element Q1 by the voltage divided by the voltage distribution of the resistors R1 and R6. The voltage divided by the voltage distribution of R2 and R7 turns on the switching element Q2. This is possible when the switching elements Q5 and Q6 are turned off. When the switching element Q6 is turned on by the first control signal S1 even when the boost voltage VC reaches a predetermined level. When the switching device Q2 is turned on and the switching device Q1 is turned off and the switching device Q5 is turned on by the second control signal S2, the switching device Q1 is turned on and switched. Element Q2 is turned off.

When the first control signal S1 and the second control signal S2 are applied to supply the microcurrent, the microcurrent supply is started.

When the switching devices Q6 and Q3 are turned on by the first control signal S1 and the switching devices Q5 and Q4 are turned off by the second control signal S2, the switching device Q2. ) Is turned on, and the microcurrent is supplied to the human body through the switching element Q2 and the human body contact terminal P1 at the first node n1, and the microcurrent supplied to the human body is the human body contact terminal P2 and It is recovered through the switching element Q3 and the resistors R8 and R9. At this time, the switching elements Q5, Q4, and Q1 are turned off by the second control signal S2. At this time, the microcurrent supplied to the human body has a positive phase, as shown in the microcurrent graphs P1-P2 of FIG. 5.

Thereafter, when the switching devices Q6 and Q3 are turned off by the first control signal S1 and the switching devices Q5 and Q4 are turned on by the second control signal S2, the switching device Q1. ) Is turned on, and the microcurrent is supplied to the human body through the switching element Q1 and the human body contact terminal P2 at the first node, and the microcurrent supplied to the human body is the human body contact terminal P1 and the switching element ( Q4), it is recovered through the resistors R8 and R9. At this time, the switching elements Q6, Q3, and Q2 are turned off by the first control signal S2. At this time, the microcurrent supplied to the human body has a negative phase, as shown in the microcurrent graph P1-P2 of FIG. 5.

As already described, the level of microcurrent supplied to the human body is different for each human body because the skin resistance is different for each human body. Therefore, in order to increase the effect of massage or treatment, a microcurrent within a certain level range must be supplied, thereby raising the necessity of checking the level of the microcurrent actually supplied to the human body.

Therefore, the microcurrent output unit 330a has a configuration capable of controlling the level of the microcurrent supplied to the human body by checking the level of the microcurrent recovered through the human body contact terminals P1 and P2.

It is possible to use the voltage corresponding to the microcurrent or the microcurrent flowing through the resistors R8 and R9 as the supply level confirmation signal MC for confirming the human body supply level of the microcurrent supplied to the human body.

The supply level confirmation signal MC may send a microcurrent flowing through the resistors R8 and R9 to the control unit 310a, and is distributed through voltage distribution of the resistors R8 and R9 as shown in FIG. It is also possible to use the supplied voltage level as the supply level confirmation signal MC.

The supply level confirmation signal MC is provided to the control chip U2 of the control unit 310a, and when the supply level confirmation signal MC is provided, the control unit 310a analyzes the supply level confirmation signal MC to the human body. It is confirmed whether the level of the microcurrent actually supplied is the desired level.

If the level of the microcurrent actually supplied to the human body is within the desired level range, no separate operation is performed, but if the level of the microcurrent is out of the desired level range, the boosting unit 320a is boosted through the third control signal S3. The level of the voltage VC is controlled.

When the level of the boosted voltage VC is controlled, the level of the microcurrent actually supplied to the human body through the human body contact terminals P1 and P2 is changed, and the control through the control unit 310a is controlled by the human body. The level of microcurrent actually supplied is continued until the desired level range is reached.

11: inner 12: outer
14: planar heating element 15: magnetic pole member
17: connection patch 18: auxiliary stimulation member

Claims (9)

Endothelial and outer shell formed in a band shape, made of a non-conductive material;
A plurality of magnetic pole members attached to the inner surface of the endothelium and made of a conductive material; And
And a microcurrent generator electrically connected to the plurality of magnetic pole plates to supply microcurrents to the magnetic pole plates. The method of claim 1,
A planar heating element is interposed between the endothelium and the outer skin, and the planar heating element is composed of a heating element coated with a heat generating layer made of a polymer mineral containing carbon, and the temperature control part is electrically connected to the planar heating element. A band for stimulating microcurrent. The method of claim 1,
The magnetic pole member for microcurrent stimulation, characterized in that the magnetic pole member is formed of any one of the conductive rubber, conductive metal, conductive fabric attached to the inner surface of the endothelial. The method of claim 1,
At least one connection patch is connected to the microcurrent generator through a wire, and the connection patch is a sub-pole for microcurrent stimulation, characterized in that the auxiliary magnetic pole plate is provided. The method of claim 1,
The microcurrent generator,
Generating a first control signal for generating a microcurrent having a positive phase, a second control signal for generating a microcurrent having a negative phase, and a third control signal for boosting a power supply voltage to control the microcurrent generation And checking the level of the microcurrent supplied to the human body through the microcurrent generator and controlling the third control signal to change the voltage level of the boosted voltage when the level is not a predetermined level. Control unit for controlling the;
A booster boosting a power supply voltage to a boosted voltage of a predetermined level in response to the third control signal of the control unit; And
On the basis of the boosted voltage boosted by the booster, a microcurrent of a desired level is generated and supplied to a specific part of the human body through connection terminals connected to the human body. And a microcurrent output unit for supplying the microcurrent having a phase and supplying the microcurrent having a negative phase when the second control signal is input. The method of claim 5,
The microcurrent output unit includes at least one voltage distribution circuit and a plurality of switching elements, and each of the plurality of switching elements performs a switching operation in response to the first control signal or the second control signal. Band for microcurrent stimulation. The method of claim 6,
The microcurrent output unit generates and supplies a supply level confirmation signal for confirming a human supply level of the microcurrent supplied to the human body, and provides the control unit, and the control unit generates a boosted voltage in response to the supply level confirmation signal. Band for microcurrent stimulation characterized by controlling the level. The method of claim 6,
The first control signal and the second control signal is a pulse signal having a predetermined period and a certain duty ratio, the first control signal and the second control signal is a micro-current stimulus, characterized in that the phase difference. The method of claim 7, wherein
The control unit checks whether the human body connection terminals are actually connected to the human body through the supply level confirmation signal, and controls whether or not microcurrent is generated.

Images