KR100945145B1 - An inner sole built-in with stimulus device of minuteness electric - Google Patents

Abstract

PURPOSE: A shoe insole having a microcurrent stimulator is provided to enhance blood circulation and to promote growth of body length. CONSTITUTION: A shoe insole having a microcurrent stimulator comprises: a microcurrent stimulator(10) which generates microcurrent; an insole(40) having a body of the stimulator at one inner side; and a stimulation member mounted to expose the surface to contact foot point for acupuncture. The microcurrent stimulator comprises: a rectangular body having a space inside; a floating magnet of disc form which flows in the space; a coil(17) generating microcurrent and magnetic field by interaction with floating magnetic; a cover preventing outflow of floating magnet; and stimulation member(18,19) stimulating microcurrent to human body.

Description

An inner sole built-in with stimulus device of minuteness electric}

The present invention relates to a shoe insole with a built-in microcurrent stimulation device, and more particularly, by the interaction of a magnet and a fixed coil flowing when a person shakes due to movement or walking while wearing shoes. The micro-current stimulator that generates electric current and magnetic field semi-permanently is built into the insole of the shoe to provide the exercise effect by repeating the contraction and relaxation of the plantar muscles, and to reduce the lactic acid of the muscles to feel less fatigue Enzyme changes not only prevent oxidase activity, but also increase the distribution of capillaries in the muscles, which helps peripheral blood vessels to increase blood flow and stimulates growth plate by stimulating growth plate by microcurrent stimulation. And it relates to a shoe insole with a microcurrent stimulation device that can contribute to the activation.

In general, the main technical contents developed for shoes are to maximize the shock and load applied to the human knee and sole when walking or running, or to minimize the weight of the shoes using special materials, or to ventilate the inside of the shoes. It focuses on technical matters such as suppressing the production of sweat by smoothing the sweat.

In particular, insoles, which are manufactured and used as a part of shoes, have been developed with a focus on technology that can absorb shocks in direct contact with the soles of the human body. Although many technical developments have been made in recent years, it has been proposed that a microcurrent stimulator is built into the insole as various beneficial effects are known when applying a microcurrent stimulus to the human body in recent years.

In other words, a weak (micro) current, called a biocurrent, flows through the human body, and the cerebral and organ organs transmit information to each other to maintain health, and when the health is not good, the biocurrent becomes weak and unstable. In addition, microcurrent is known to have a function of actively supporting metabolism and blood circulation and eventually increasing natural healing power.

In other words, the appropriate microcurrent (about 0.06mA) is the weak alkaline of the blood, the expansion of blood vessels, the normalization of blood pressure, the diuretic action, the normalization of the pulse, the strengthening of the heart, the increase of collagen synthesis rate, the promotion of leukocytes, the bactericidal effect, the bacterial growth inhibition. It has been shown medically to be effective in inhibiting E. coli growth, improving microvascular blood circulation, promoting protein synthesis capacity, doubling treatment speed, promoting fatigue recovery, correcting autonomic nerves, promoting growth, purifying water, and removing odors. (Borgens et al .; Barker, Jasffe and Vanable, 1982; Borgens et al., 1980) (Korean Journal of Physical Therapy Vol. 16, No. 3) (Korean Journal of Professional Physiotherapy, Vol. 3, No. 1) (Korean Journal of Physical Therapy Vol. 6 1) (Research Paper, Prof. Lee Tae-kyu, Kim Mun-chan, Professor of Neurosurgery, Gangnam St. Mary's Hospital).

As another example, Kim, Jun Orthopedic Kwon, Won Ahn, Department of Physiotherapy, College of Rehabilitation Science, Daegu University, Park, Rae-Joon, Department of Physiotherapy, College of Health, Daegu Health, and Tae-Hwang Hwang, Department of Physiotherapy, Chonnam College of Science (Alon, 1986; Barron 1985; Carley, Wainapel, 1985) and animal experiments (Alvare, 1983; Bourguigron, 1987; Cheng, 1982; Suzuki, 1986) show that microcurrent stimulation stimulates tissue healing and repair processes. The studies used provide evidence that intracellular ATP resynthesis, protein synthesis, and DNA replication rates are increased by direct electrical stimulation.

The effects of the microcurrent stimulation have the effects of pain relief (direct pain reduction by directly blocking the propagation of the action potential), edema reduction (reduction of edema due to the movement of body fluid), and the effect and metabolism of the electrical stimulation on muscles It is divided into changes in action and changes in blood vessels.

In other words, the effect of microcurrent stimulation on the muscles, the muscles are moved by electrical stimulation through the nerve cells, stimulating the surface of the muscles with an electrotherapy device, when a certain amount of electricity enters, namely muscle atrophy It can delay the progression of the reduced state, and it has a motor effect by the repetitive action of contraction and relaxation, and the cooperative muscle is also activated.

As a metabolic change, experiments have demonstrated that the stimulated muscles can feel less fatigue such as reduced lactic acid and prevent oxidase activity due to changes in enzymes. As the distribution increases, peripheral blood vessels expand to help improve blood flow. (Park, Ra-Joon, Ph.D. Professor, Department of Physiotherapy, College of Rehabilitation Science, Daegu University)-The effect of microcurrent of pulsating electromagnetic energy on wound healing of rabbit-Korean Physics The Journal of Therapeutics Vol. 12, No. 3)

Therefore, the Republic of Korea Patent Publication No. 2006-114824 (published: November 08, 2006) in the soles of the sole by incorporating an electrical operation circuit consisting of a magnetic pole, a control unit, a power supply, an interface, a display, a remote control unit in the sole Shoe insoles have been proposed as an electrical stimulation technique that provides the effect of electrically massaging the soles of the feet, but the configuration is complicated and the volume of the electronic circuit is increased due to the use of a battery, making it impossible to install inside the insole. There are many problems to be put to practical use.

In addition, Korean Patent No. 669125 (Registration Date: 2007.01.09) proposes a method of promoting elongation growth by stimulating the growth plate by installing an electric stimulation member that generates a microcurrent or low frequency of tens to hundreds of microwatts in a shoe. The current generator for generating the microcurrent or low frequency used in the Korean Patent No. 669125 can be classified into three types.

Firstly, it is composed of a battery for power supply and an electric circuit by electronic components such as capacitors, resistors, transistors, variable resistors, switches, and the like, and converts electricity supplied from the battery into microcurrents of several hundreds to hundreds of microamps. It consists of a microcurrent generator, and secondly, the microcurrent is generated by the internal resistance of the power generation point itself formed at the end of the heel stimulus of the ankle, and thirdly, the voltage and the microcurrent according to the applied pressure. The piezoelectric element is generated.

As the first current generating device described above is composed of a microcurrent generating source consisting of a battery and a plurality of electronic components, there is a problem in that the function of promoting the growth of the kidney is not obtained because the operation of the electric stimulation member is stopped when the life of the battery runs out. In particular, the life of the battery itself is extremely short, which requires a lot of maintenance costs due to frequent battery replacements, as well as securing the space required for battery replacement and watertightness for the protection of electronic components. There are many problems with the image.

The second current generator described above allows the microcurrent to be generated by the internal resistance of the power generation point itself, but the current generated by the internal resistance of the power generation point itself is in the range of tens to hundreds of mA for stimulation of the growth plate. There is a problem that can not achieve the effect of promoting the growth of the kidneys as extremely weak current is generated at all.

The third current generator described above uses a piezoelectric element that generates a voltage and a microcurrent according to the applied pressure, but the amount of current and voltage generated by the piezoelectric element is basically proportional to the external force applied from the outside. In general, the voltage may increase or vary depending on the material and the size and shape of the device. The voltage may be formed from several volts to several thousand volts, but the amount of current is usually very small.

Therefore, the Korean Patent No. 669125 described above is manufactured in a form in which several tens to hundreds of layers are laminated instead of a single layer in order to generate a microcurrent required from a piezoelectric element. The manufacturing cost of the device is formed very high, which is a problem that the burden on the consumer is increased because the actual shoe price is increased together.

The present invention can be manufactured at low cost and small size, and generates semi-permanently micro currents and magnetic fields by the interaction of a fixed coil and a moving magnet when a person shakes due to movement or walking while wearing shoes. Built-in current stimulator insole provides exercise effect by repeating contraction and relaxation of plantar muscles, reducing lactic acid in muscle, less fatigue and preventing oxidase activity due to enzyme changes. As the distribution of capillaries increases in the peripheral blood vessels to help to increase blood flow, and to stimulate the growth plate by microcurrent stimulation to contribute to the promotion and activation of kidney growth.

The present invention is a rectangular body having a space portion formed therein, a disk-shaped flow magnet flowing into the space portion, the coil is installed on the outer surface of the body to generate a microcurrent and magnetic field by interaction with the flow magnet And a microcurrent stimulation device provided at both ends of the body to prevent leakage of the flow magnet, and a stimulation member installed at both ends of the coil to apply microcurrent stimulation to the human body. The body of the microcurrent stimulation device is installed on one side of the insole, the stimulation member is characterized in that it is exposed to the surface so as to contact the acupuncture points of the human foot.

The present invention provides a cylindrical body having a space portion therein, a cylindrical flow magnet flowing into the space portion, a coil installed on the outer surface of the body to generate a microcurrent by interacting with the flow magnet, and Covers are installed at both ends of the body to prevent the flow of the flow magnet, and fixed magnets are provided on one inner surface of the cover and have the same polarity as the polarity of the flow magnet, and are installed at both ends of the coil And a microcurrent stimulation device comprising a stimulation member for applying stimulation to the human body, the body of the microcurrent stimulation device is installed on one side of the insole, and the stimulation member is exposed to the surface to be in contact with the menstrual blood of the sole of the human body. It is characterized by.

The present invention is provided with a body having a space formed therein and the bottom is closed, the bottom surface of the body is fixed to the first coil is connected to both ends of the magnetic pole member, the upper surface of the first coil flows A magnet is disposed, and a microcurrent stimulation device provided with a cover for preventing separation of the magnet is provided above the end of the body, the body of the microcurrent stimulation device is installed on one side of the insole, the magnetic pole The member is characterized in that it is installed exposed to the surface in contact with the acupuncture points of the human foot.

As another embodiment of the present invention, one side of the body is formed with a recess to prevent the separation of the coil, characterized in that to generate a micro-current of 10 ~ 200㎂ by the interaction of the coil with the flow magnet.

As another embodiment of the present invention, the magnetic pole member is provided with a conductive sheet formed of a conductive sheet having a thickness of 0.01 to 0.5 mm or a conductive network made of a woven fiber with a conductive sheet having a thickness of 0.01 to 0.5 mm. The upper surface of the conductive sheet and the conductive network is characterized in that the protruding contact protrusions in contact with the acupuncture points of the human foot and the skin.

The present invention can be manufactured at low cost and small size, and generates semi-permanently micro currents and magnetic fields by the interaction of a fixed coil and a moving magnet when a person shakes due to movement or walking while wearing shoes. Built-in current stimulator insole provides exercise effect by repeating contraction and relaxation of plantar muscles, reducing lactic acid in muscle, less fatigue and preventing oxidase activity due to enzyme changes. As the distribution of capillaries increases, peripheral blood vessels are expanded to help blood flow, and stimulation of growth plates by microcurrent has the effect of contributing to the promotion and activation of kidney growth.

In addition, the present invention is not only possible to manufacture a simple structure, low cost and miniaturization and have a semi-permanent life, there is no need for a separate power supply such as a battery, there is an effect that does not require any maintenance costs.

Hereinafter, a shoe insole incorporating the microcurrent stimulation apparatus according to the present invention will be described in detail with reference to FIGS. 1A to 6C.

1A is a perspective view of a shoe insole having a microcurrent stimulation device according to the present invention, and FIG. 1B is a cross-sectional view of the EE line of FIG. 1A, which is installed at one side of the insole 40 and is fixed to a magnet that is moved or moved when walking. The microcurrent stimulation apparatus 10 for semi-permanently generating the microcurrent and the magnetic field by the interaction of the coil is installed, and the microcurrent generated from the microcurrent stimulation apparatus 10 at a predetermined position of one side of the insole 40. Stimulation members (18) and (19) for contact with acupuncture points or muscles of the sole of the human body to apply stimulation are exposed to the surface.

2A is a perspective view showing one embodiment of the microcurrent stimulation apparatus 10 used in the present invention, FIG. 2B is an exploded perspective view of the microcurrent stimulation apparatus 10 shown in FIG. 2A, and FIG. 2C is shown in FIG. 2A. AA and BB lines are cross-sectional views of the microcurrent stimulation apparatus 10 shown in FIG. 2, and FIG. 2D is an operation state diagram of the microcurrent stimulation apparatus 10 shown in FIG. 2A.

That is, a space portion 16a-1 is formed inside and has a rectangular body 16a having a height greater than a width, and a disk-shaped flow magnet in the space portion 16a-1 formed in the body 16a. 15a is introduced, and a coil 17 is wound around the outer surface of the body 16a to generate a microcurrent and a magnetic field by interacting with the flow magnet 15a.

In addition, one side is closed at both ends of the body (16a), the cover 11, 12 to prevent the flow of the flow magnet (15a) is installed inflow, both ends of the coil 17, the sole of the human foot The stimulation member (18) and (19) for contact with the menstrual blood and the skin (muscle) of the stimulus are connected.

Here, the stimulating members 18 and 19 are preferably used a conductive material that does not damage the skin when the body is in contact, and can be installed in various ways depending on the stimulation portion, the number of installation is not limited.

Referring to the process of stimulating the current in a state in which the insole 40 is built in the microcurrent stimulation device 10 according to the present invention made as described above installed in the shoe as follows.

First, when the user wears shoes, the stimulating members 18 and 19 come into contact with acupuncture points and muscles of the soles of the human body.

In this state, as shown in FIG. 2C, when the user does not move or is not walking, the body 16a maintains a stationary state in which the flow magnet 15a introduced therein does not move. Will not occur.

However, when the inclination occurs between the body 16a and the ground as shown in FIG. 2D due to the user moving or walking, the space magnet 16a is formed inside the body 16a by the inclination angle. It flows back and forth within 1).

At this time, an induced current and a magnetic field are generated in the coil 17 wound on the outer surface of the body 16a due to the flow generated in the space 16a-1 in which the flow magnet 15a is formed inside the body 16a. The generated induction current, that is, the microcurrent is transmitted to the stimulus members 18 and 19 to apply a microcurrent stimulus to the menstrual blood and the skin of the sole, and at the same time a magnetic field is applied to the stimulus member 18. (19) is to stimulate the soles.

Figure 3a is a perspective view showing another embodiment of the microcurrent stimulation apparatus used in the present invention, Figure 3b is an exploded perspective view of the microcurrent stimulation device shown in Figure 3a, Figure 3c is a microcurrent stimulation device shown in Figure 3a Is a cross-sectional view taken along lines CC and DD, and FIG. 3D is a state diagram of the microcurrent stimulation apparatus shown in FIG. 3A.

That is, the inside is provided with a cylindrical body 16b having a space portion 16b-1 formed therein, and the cylindrical magnet 16b-1 flows into the space portion 16b-1 formed inside the body 16b. On the outer surface of the body 16b, a coil 17 for generating a microcurrent in interaction with the flow magnet 15b is wound.

In addition, one side is closed at both ends of the body 16b, and covers 11 and 12 are installed to prevent the outflow of the flow magnet 15b, and one side inner surface of the cover 11 and 12 is provided. Fixing magnets 13 and 14 having the same polarity as that of the floating magnet 15b are provided, respectively, and both ends of the coil 17 are in contact with the human body to apply magnetic poles 18. (19) is connected.

Here, the Gaussian value of the stator magnets 13 and 14 should be much smaller than the Gaussian value of the floating magnet 15b. This is because when the Gaussian value of the stator magnets 13 and 14 is larger than the Gaussian value of the flow magnets 15b, the flow distance of the flow magnets 15b is shortened, so that the desired microcurrent cannot be obtained.

In addition, the polarities of the stator magnets 13 and 14 corresponding to the ends of the floating magnets 15b have the same polarity as those of the floating magnets 15b so that a repulsive force acts so that the impact magnets are not applied. Due to the attraction and repulsive action of the fixed magnets 13 and 14, the floating magnet 15b floats inside the space 16b-1 to maintain a stopped state without flow. When an impact is applied, an imbalance occurs in the attractive force and the repulsive force due to the impact, so that the flow magnet 15b flows left and right in the space portion 16b-1 formed in the body 16b.

Referring to the electrical stimulation process in a state in which the insole 40, which is embedded in the microcurrent stimulation apparatus 10 of another embodiment used in the present invention made as described above inflow to the sole surface of the shoe is as follows.

First, when the user wears shoes, the stimulating members 18 and 19 installed in the insole 40 come into contact with the acupuncture points and the skin of the sole of the foot.

In this state, as shown in (a) of FIG. 3C, when the user is not moving or walking, the flow magnets 15b introduced into the body 16a are mutually fixed by the stator magnets 13 and 14. The attraction force and the repulsive force act to maintain the suspended state floating in the space 16b-1, so that the microcurrent is hardly generated in the coil 17.

However, when walking is made, the weight of the user is transmitted to the ground, and an impact is generated. As the impact is transmitted to the microcurrent stimulation device 10, between the stationary magnets 13 and 14 and the floating magnet 15b. The imbalance between the formed attraction force and the repulsive force causes the flow magnet 15b to flow in the left and right directions within the space portion 16b-1 formed in the body 16b.

At this time, an induced current and a magnetic field are generated in the coil 17 wound on the outer surface of the body 16b due to the flow generated in the space 16b-1 in which the flow magnet 15b is formed inside the body 16b. The generated induction current, that is, the microcurrent is transmitted to the stimulation members 18 and 19, and the magnetic field is applied to the menstrual blood and the skin of the sole through the stimulation members 18 and 19. By being applied around this, an electrical stimulus is applied.

FIG. 4 shows another embodiment of the bodies 16a and 16b in the microcurrent stimulation apparatus 10 shown in FIGS. 2A to 2D and 3A to 3D, and FIG. The recessed part 16c by forming the step part 16d is formed in one side surface of 16a, 16b, and FIG. 4 (b) shows the step part in the front surface of one side of the said body 16a, 16b. By forming the recessed portion 16c by the formation of 16d, the coil 17 is prevented from slipping off from the bodies 16a and 16b.

Figure 5a (a), (b) is an exploded perspective view and cross-sectional view showing another embodiment of the microcurrent stimulation apparatus used in the present invention, the body 41 is formed with a space portion and the bottom surface is closed It is provided, the bottom surface of the body 41 is wound to a predetermined thickness, both ends of the first coil 42 to which the magnetic pole member 18, 19 is connected is fixedly installed, the first coil 42 The upper surface of the flow magnet 43 is disposed, the upper end of the body 41, the cover 44 to prevent the separation of the magnet 43 is provided to form a structure.

The flow magnet 43 has a suitable space portion 47 between the first coil 42 and the inner surface of the cover 44 so that the left and right flow can be free.

When the user is not moving or walking while the insole 40 in which the microcurrent stimulation device 10 of the other embodiment is formed as described above is introduced into the shoe, the floating magnet 43 is a microcurrent stimulation device ( Since no inclination of 10) does not flow in the front-rear direction on the first coil 42, a microcurrent hardly occurs in the first coil 42.

However, when the inclination occurs between the microcurrent stimulation device 10 and the ground due to the user's movement or walking, the flow magnet 43 is formed in the space 47 formed inside the body 41 by the inclination angle. It flows forward and backward.

At this time, when the flow magnet 43 flows left and right on the upper surface of the first coil 42, an induced current and a magnetic field are generated in the first coil 42. The generated induced current, that is, the microcurrent is not shown. The magnetic field is applied to the periphery of the stimulus members 18 and 19 and the microcurrent stimulus is applied to the menstrual blood and muscles of the sole through the stimulus members 18 and 19.

5A and 5B are exploded perspective views and cross-sectional views showing another embodiment of the microcurrent stimulation apparatus shown in FIG. 5A, wherein a body 47 is formed therein and the bottom surface is closed ( 41 is provided, and the first coil 42 is fixed to the bottom surface of the body 41 is connected to the magnetic pole member 18, 19 is connected to both ends is fixed, the first coil A floating magnet 43 is disposed on an upper surface of the 42, and a cover 44 is installed above the end of the body 41 to prevent the magnet 43 from being separated. An inner surface of the cover 44 is provided. Has a structure in which the second coil 45 is fixedly installed.

The flow magnet 43 has a suitable space portion 47 so that the left and right flow freely between the first coil 42 and the second coil 45.

When the user is not moving or walking while the insole 40 installed with the microcurrent stimulation apparatus 10 according to another embodiment made as described above is introduced into the shoe, the microcurrent stimulation apparatus 10 does not incline. Therefore, the flow magnet 43 does not flow back and forth in the space portion 47 between the first and second coils 42 and 45, and thus the first and second coils 42 and 45 ), The microcurrent rarely occurs.

However, when the inclination occurs between the microcurrent stimulation device 10 and the ground due to the user's movement or walking, the flow magnet 43 is formed in the space 47 formed inside the body 41 by the inclination angle. It flows forward and backward.

In this case, when the flow magnet 43 flows left and right between the first and second coils 42 and 45, an induced current and a magnetic field are simultaneously generated from the first and second coils 42 and 45. The generated induction current, that is, microcurrent is transmitted to the stimulus members 18 and 19, not shown, and at the same time a magnetic field is applied to the periphery of the sole and the skin of the sole through the stimulus members 18 and 19. Current stimulation.

Therefore, in the embodiment of FIG. 5B, the flow magnet 43 may flow between the first and second coils 42 and 45 to generate more microcurrent and magnetic field than the embodiment of FIG. 5A.

Further, the fine current generated from the microcurrent stimulation apparatus 10 in the embodiment shown in Figs. 2A to 2D, the embodiments in Figs. 3A to 3D, and the embodiment shown in Figs. 5A and 5B of the present invention. The electric current provides the exercise effect by the repetitive action of muscle contraction and relaxation by stimulating the menstrual blood and muscles of the sole of the human foot, reducing the lactic acid of the muscle, feeling less fatigue and preventing the oxidase activity due to the change of enzyme. Rather, as the distribution of capillaries in the muscle increases, peripheral blood vessels expand to increase blood flow as well as to promote renal growth through stimulation of growth plates. The desired microcurrent can be obtained by adjusting the Gaussian values of the coils 15b and 43 and the number of turns of the coils 17, 42 and 45.

In general, the repetitive action of muscle contraction and relaxation provides the exercise effect, reduces the lactic acid in the muscle, reduces fatigue, prevents oxidase activity due to enzyme changes, and increases the distribution of capillaries in the muscle Blood vessels can be expanded and blood flow can be expected, and a preferable microcurrent that can promote kidney growth by stimulating the growth plate of the human body is about 10 to 200 mA, and the flow magnets 15a, 15b, and 43 are 500 to 3,000. Gaussian, coils 17, 42, 45 can be seen through the experimental results that the micro-current in the range of 10 ~ 200 Ω generated from the micro-current stimulation apparatus 10 of the present invention when winding 500 to 20,000 times .

Here, the Gaussian values of the floating magnets 15a, 15b and 43 and the number of turns of the coils 17, 42 and 45 may vary depending on the desired degree of generation of the microcurrent, and thus the range is not limited.

In particular, the microcurrent stimulation apparatus 10 in the embodiment shown in Figs. 2A to 2D, the embodiment shown in Figs. 3A to 3D, and the embodiment shown in Figs. 5A and 5B has a speed of walking. The greater the impact on the ground due to faster or jogging, the greater the flow range of the flow magnets 15a, 15b, 43, and the faster the flow rate. And the like can be maximized.

In addition, the microcurrent stimulation apparatus 10 of the embodiment shown in Figs. 2A to 2D, the embodiment shown in Figs. 3A to 3D, and the embodiment shown in Figs. Although it may be provided in the part, it is preferable that it is provided in the arch part which contacts the midfoot arch of the sole which is thickest in the insole 40.

Figure 6a is a perspective view and a cross-sectional view showing another embodiment of the magnetic pole member 18, 19 in the microcurrent stimulation apparatus according to the present invention, Figure 6b is another of the magnetic pole member 18 (19) shown in Figure 6a 6C is an exemplary view showing a state in which the magnetic pole members 18 and 19 shown in FIGS. 6A and 6B are installed in the insole 40, and microcurrent stimulation can be performed simultaneously on a large portion of the sole of the foot. I would have to.

That is, as shown in (a) and (b) of FIG. 6A, a conductive sheet 51 having a plate shape as a conductive material having a thickness of 0.01 to 0.5 mm is provided, and a human body is disposed on an upper surface of the conductive sheet 51. Contact protrusions 52 in contact with the menstrual blood and the skin of the sole form a protruding structure.

In addition, as shown in Figure 6b the material is a conductive material having a thickness of 0.01 ~ 0.5mm thick conductive material 53 is made of woven in the form of a fiber, the upper surface of the conductive network 53 and the acupuncture points of the human foot and skin The contact protrusions 52 in contact with each other form a protruding structure.

The conductive sheets 51 and the conductive nets 53 may be made of gold, silver, or the like having a very low electrical resistance, but it is preferable to use copper from an economical point of view. In addition, the type thereof is not limited, and the contact protrusions 52 formed on the conductive sheet 51 and the conductive network 53 are formed through a pressing work process of a bottom surface.

6A and 6B, the magnetic pole members 18 and 19 of the other embodiments shown in FIGS. 6A and 6B are installed in the insole 40 or installed on the surface by sewing, as shown in FIG. 6C, wherein the contact protrusions 52 are provided. ) By exposing to the outside of the skin of a large area of the human foot at the same time to apply a microcurrent stimulation and magnetic field multiple times to increase the efficiency, it is possible to apply to a variety of items because there is an advantage that can be sewn.

Wherein the conductive sheet 51 and the conductive net 53 is formed when the thickness is less than 0.01mm is feared to be broken when washing the insole 40, when formed with a thickness of 0.5mm or more increases the price and load and flexibility There is a problem that damage is caused to damage the human body is preferred to have a thickness in the range of 0.01 ~ 0.5mm.

As such, the present invention provides a microcurrent stimulator for semi-permanently generating microcurrents and magnetic fields in the insole to provide a motor effect by the stimulation of the plantar acupoints and the repetitive action of muscle contraction and relaxation, reducing the lactic acid in the fatigue Not only can the oxidase activity be prevented due to changes in enzymes, and the distribution of capillaries in the muscles increases, thereby expanding peripheral blood vessels and helping blood flow, and stimulating growth plates by microcurrent stimulation. It can contribute to the promotion and activation of growth.

Figure 1a is a perspective view of a shoe insole with a microcurrent stimulation device according to the present invention.

1B is a cross-sectional view taken along the line E-E in FIG. 1A.

Figure 2a is a perspective view showing one embodiment of a microcurrent stimulation apparatus used in the present invention.

Figure 2b is an exploded perspective view of the microcurrent stimulation device shown in Figure 2a.

2C is a cross-sectional view taken along line A-A and line B-B of the microcurrent stimulation apparatus shown in FIG. 2A.

FIG. 2D is an operational state diagram of the microcurrent stimulation apparatus shown in FIG. 2A.

Figure 3a is a perspective view showing another embodiment of a microcurrent stimulation apparatus used in the present invention.

Figure 3b is an exploded perspective view of the microcurrent stimulation device shown in Figure 3a.

3C is a cross-sectional view taken along line C-C and D-D of the microcurrent stimulation apparatus shown in FIG. 3A.

3d is an operating state diagram of the microcurrent stimulation apparatus shown in FIG. 3a.

Figure 4 is a cross-sectional view showing another embodiment of the body in the microcurrent stimulation device shown in Figures 2a to 2d and 3a to 3d.

Figure 5a (a), (b) is an exploded perspective view and cross-sectional view showing another embodiment of the microcurrent stimulation apparatus used in the present invention.

5A and 5B are exploded perspective views and cross-sectional views showing another embodiment of the microcurrent stimulation apparatus shown in FIG. 5A.

Figure 6a is a perspective view and a sectional view showing another embodiment of the magnetic pole member in the microcurrent stimulation apparatus used in the present invention.

Figure 6b is a perspective view and a sectional view showing another embodiment of the magnetic pole member shown in Figure 6a.

Figure 6c is an illustration of a state in which the magnetic pole member of the other embodiment of Figures 6a and 6b is installed in the insole.

[Description of Symbols for Main Parts of Drawing]

10: microcurrent stimulation device 11, 12: cover

13, 14: fixed magnet 15a, 15b: floating magnet

16a, 16b: body 16c: groove

16d: step 17: coil

18, 19: magnetic pole member 40: insole

41 body 42: first coil

43: fluid magnet 44: cover

45: second coil 47: space part

51: conductive sheet 52: contact projection

53: challenge network

Claims (8)

A rectangular body 16a having a space 16a-1 formed therein, a disk-shaped flow magnet 15a flowing into the space 16a-1, and an outer surface of the body 16a. And a coil 17 for generating a microcurrent and a magnetic field by interacting with the flow magnet 15a, and a cover 11 installed at both ends of the body 16a to prevent the flow of the flow magnet 15a. 12 and a microcurrent stimulation device (10) consisting of magnetic pole members (18) and (19) installed at both ends of the coil (17) to apply microcurrent stimulation to the human body. The body 16a of the microcurrent stimulation device 10 is installed on one side of the insole 40, Shoe insole with a microcurrent stimulation device, characterized in that the stimulation member (18) (19) is installed exposed to the surface in contact with the acupuncture points of the human foot. Cylindrical body 16b having a space portion 16b-1 formed therein, a cylindrical flow magnet 15b flowing into the space portion 16b-1, and installed on the outer surface of the body 16b. And a coil 17 for generating a microcurrent by interacting with the flow magnet 15b, and a cover 11 installed at both ends of the body 16b to prevent the flow of the flow magnet 15b. 12) and stator magnets 13 and 14 installed on one inner surface of the cover 11 and 12 and having the same polarity as that of the floating magnet 15b, and both ends of the coil 17. The microcurrent stimulation device 10 is provided with a magnetic pole member (18, 19) is installed in the portion to apply a stimulus to the human body, The body 16b of the microcurrent stimulation device 10 is installed on one side of the insole 40, Shoe insole with a microcurrent stimulation device, characterized in that the stimulation member (18) (19) is installed exposed to the surface in contact with the menstrual blood of the sole of the human body. A space 41 is formed therein, and a body 41 having a closed bottom surface is provided, and a first coil 42 having both ends connected to the magnetic pole members 18 and 19 at the bottom surface of the body 41 is provided. Is fixedly installed, the floating magnet 43 is disposed on the upper surface of the first coil 42, the cover 44 is installed on the upper end of the end of the body 41 to prevent the magnet 43 from being separated The microcurrent stimulation device 10 is formed, The body 41 of the microcurrent stimulation device 10 is installed on one side of the insole 40, Shoe insole with a microcurrent stimulation device, characterized in that the stimulation member (18) (19) is installed exposed to the surface in contact with the menstrual blood of the sole of the human body. The sole of claim 1 or 2, wherein one side of the body (16a, 16b) is formed with a groove portion (16c) for preventing the separation of the coil (17). . The microcurrent of any one of claims 1 to 3 is generated by interaction between the flow magnets 15a, 15b, 43 and the coils 17, 42. Shoe insole with a microcurrent stimulation device characterized in that. According to any one of claims 1 to 3, wherein the magnetic pole member 18, 19 is a conductive material of the plate-shaped conductive sheet 51 is provided with a thickness of 0.01 ~ 0.5mm, Shoe insole with a built-in microcurrent stimulation device, characterized in that the projecting contact 52 is formed on the upper surface of the conductive sheet 51 in contact with the skin of the human foot. According to any one of claims 1 to 3, wherein the magnetic pole member 18, 19 is provided with a conductive net 53 made of a woven fiber form as a conductive material of 0.01 ~ 0.5mm thickness, Shoe insole with a built-in microcurrent stimulation device, characterized in that the projecting contact 52 is formed on the upper surface of the conductive net 53 in contact with the skin of the sole of the human body. 4. The shoe insole of claim 3, wherein the second coil 45 is fixed to the inner surface of the cover 44.

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