JP4379624B2 - Weak current activation tool - Google Patents

Description

  The present invention relates to a weak current activator that utilizes the electromotive action of physical properties and activates cellular tissue of the body with the weak current that is generated.

  It is known that the human body is made up of cells, and when you use your head or move, the more you use the cells, the more they are stimulated and activated. A bioelectric current of 100 to 200 μA flows in the body, and a series of electrical changes occur in the cell membrane due to weak current stimulation in nerve fibers and muscle fibers, and an adjacent portion is caused by an electrical change generated in one place. Being stimulated one after another, it has the property that the excitement is transmitted through the fibers. When the bioelectric current is disturbed by the cellular tissue and becomes an obstacle to the ionic arrangement of the cellular tissue and does not flow smoothly, the natural healing power inherent in humans is reduced, causing a disease. Therefore, it has been reported in the research results of the University of Pittsburgh that cells are activated and natural healing power is increased by passing a weak current close to the bioelectric current from outside the body. Weak current therapy (microcurrent therapy) is the treatment method. There is. When an individual cell or tissue is damaged by the weak current therapy, an ATP (adenosine triphosphate) enzyme that supplies energy necessary for the repair by artificially sending a weak (= damage) current from outside the body. It has been proved that production, protein synthesis, etc. are promoted to increase the natural healing power and accelerate healing (recovery). According to the research results of the University of Pittsburgh, there is a report that intracellular ATP synthesis is increased by 50%, protein synthesis is increased by 70%, and intercellular transport is increased by 40%. As a weak current therapy device, a weak current generator has been developed and commercialized. For example, Japanese Patent Publication No. 2005-529689 has been proposed in the publicly known publication. In the beauty salon, the weak current supplied from the weak current generator is applied to the face and scalp with a conductive glove to energize the face, promoting the activation of skin tissue in the face, and the hair growth of hair matrix cells in the scalp. Treatments that increase energy (ATP) are being conducted. Therefore, it is preferable if this weak current treatment can be done at home, but the price of an already-produced weak current generator is 100,000 yen or more, so the treatment was not easy except for going to the beauty salon.

Therefore, the present inventor has focused on the electromotive action of physical properties, and has reached the present invention. The piezoelectric effect that is generated when pressure is applied to a piezoelectric body made of a crystal or a ceramic material, or the ionization that occurs between different metals. It has the property of ionization tendency that is generated by the action of action, and if the weak current that is generated by using the action of the piezo effect and ionization tendency is caused to flow into the body, the treatment effect by the weak current described above can be obtained.
A method of generating electricity with the pressure applied to the piezoelectric body using the piezo effect will be described with reference to FIG. 19. In FIG. 19A, a force for compressing the piezoelectric body indicated by an arrow (↓) on the surface of the piezoelectric body ( When compressive stress is applied, the piezoelectric body is distorted in the direction of contraction as shown in the figure, and an electromotive current i is generated at that time. Next, when the compressing force is removed, the piezoelectric body returns to its original shape, and an electromotive force i in the opposite direction is generated at that time. In FIG. 19B, when a force (shear stress) for bending the piezoelectric body indicated by the arrows (↓ & ↑) is applied to the surface of the piezoelectric body, the piezoelectric body is distorted in the bending direction as shown in the figure, and an electromotive current is generated at that time. i is electromotive. Next, when the bending force is removed, the piezoelectric body returns to its original shape, and an electromotive force i in the opposite direction is generated at that time. In this case, since the displacement amount distorted by the bending force is much larger than the displacement amount distorted by the compressing force, the electromotive current generated by the bending force is much larger.

Patent publication 2005-529689

  The present invention has been made in view of the above-described problems, and uses the electromotive force flowing between the piezoelectric body and the dissimilar metal, and the weak current activity that allows the weak current generated efficiently to the face and scalp with no power supply. Is to provide the ingredients.

The present invention is configured by providing a piezoelectric film body that is appropriately bent as a piezoelectric body, so that the piezoelectric film body is freely deformed in that direction regardless of the pressure or external force applied from any direction to the piezoelectric film body. Each time a bending or tensile strain occurs in the piezoelectric film body, so that it can continuously generate electricity and generate a weak current, so by installing the piezoelectric film body in the right place of gloves, hitting tools, face mask, hair net, Since the piezoelectric film body that is in close contact with the palm, face and scalp surface is deformed in conjunction with its movement, the weak current generated by the piezoelectric film body due to the deformation strain is applied to the skin of the face and scalp. .
In addition, the present invention utilizes the elasticity and flexibility of metal, plastic, and rubber, and forms a substrate with metal, plastic, and rubber that has elasticity and conductivity by being appropriately bent at an appropriate thickness. By providing the piezoelectric body on the substrate in a flat and thin shape, no matter which direction pressure or external force is applied to the substrate, the piezoelectric body is bent and deformed integrally with the substrate in that direction. Since it returns to its original shape due to the elasticity it has, it can generate a weak current by continuously generating electricity against external force and pressure applied to the substrate, such as compression and bending (shearing). Is provided in the striking tool, and the scalp surface or body surface is struck by the striking tool, whereby a weak current generated by the piezoelectric body is energized in the skin.
Further, the glove of the present invention is configured such that different types of metal sheets are provided apart from each other, and a weak current flowing between both metal sheets due to an ionization tendency is applied to the skin of the face and scalp that are in contact with each other.

In the weak current active device configured by providing the piezoelectric film body of the present invention, since the piezoelectric film body is appropriately bent and freely deformed, the piezoelectric film body is subjected to compression, bending (shear), and tension applied from all directions. Even under pressure or external force, the piezoelectric film body is distorted in that direction and can continuously generate electricity to generate a weak current, so this weak current active device can be treated without a power source, Since it fits well with the shape of the body surface and deforms, it is not bulky, and since there is no power supply, no power cord is required, and any body surface can be treated while moving anywhere.
In addition, the weak current active device constituted by providing the piezoelectric body in a flat plate shape on an elastic substrate by appropriately bending the present invention, the piezoelectric body can be applied even by compression or bending (shear) pressure or external force applied from any direction. Since it deforms by distorting in that direction following the deformation of the substrate, it can continuously generate electricity and generate a weak current, and the amount of displacement due to bending deformation can be increased in the deformation, so that Treatment is possible with a weak current that can generate a very large current and generate electricity efficiently.
In addition, the weak current activation tool for gloves comprising the different metal sheets of the present invention is formed of a flat and thin metal sheet, so it can be bent freely and fits whatever shape the skin surface changes. Then, it can touch the skin surface, and similarly there is no power supply, so there is no need for a power cord, and any body surface can be treated while moving in any posture.

A configuration of an embodiment of the present invention will be described with reference to the drawings.
FIGS. 1-10 shows the structure which implemented the weak electric current active device of this invention to the glove. 1-7, each figure (a) shows the front view of the palm side of a pair of gloves, and each figure (b) is the front view of the palm side of the right glove and the side surface exploded in the XY direction. Each figure (c) shows the front view disassembled into each component. 8 to 10 show front views of the palm side of a pair of gloves.

  In FIG. 1, a glove 1A is formed of a cloth material, impregnated with a conductive carbon material to make the entire glove 1A conductive, and a conductive portion 6 is formed on the glove 1A. Then, in the center of the palm of the glove 1A, as the piezoelectric body 4 shown in FIG. 18 (c), a piezoelectric film 4b provided with electrodes 5 on the upper surface and the lower surface is connected to the conductive portion 6 on the glove 1A and the electrode 5 on the lower surface. Is pasted and configured to conduct. In this configuration, the area of the electrode 5 provided on the upper surface is slightly smaller than the area of the upper surface of the piezoelectric film 4b body, and a gap is provided between the conductive portion 6 on the glove 1A and the electrode 5 provided on the upper surface. It is configured not to touch.

  In this configuration, when the glove 1A is fitted to the hand and the palm or the entire finger is moved, the piezoelectric film 4b body is bent or stretched in the direction of bending or stretching shown in FIG. Each time, the piezoelectric film 4b generates a weak electromotive current. Then, as shown in FIG. 11, when both the gloves 1A and 1A are put on the face and the skin is massaged with the palm and the entire palm, the gap between the electrode 5 in contact with the skin and the conductive portion 6 on the glove 1A Therefore, a weak current generated by the piezoelectric film 4b flows in the skin tissue of the skin. Here, since the weak current flowing in the skin tissue is on the order of microamperes, there is no sensation of chattering, and treatment with the weak current is possible while massaging the skin on the entire palm. The off-the-shelf weak current generator applies a weak current in a fixed pattern, but the glove 1A of the present invention can randomly apply a weak current stimulus generated in various patterns in conjunction with the movement of the hand. So it is very effective. Here, the piezoelectric (piezo) film 4b constituting the present invention can be made of, for example, polyvinylidene fluoride (PVDF) manufactured by US MSI (Measurement Specialties. Inc.), and the piezoelectric (piezo) film 4b has an external force or When pressure is applied, it bends and deforms in that direction, and a weak current is generated each time. Compared with the piezoelectric (piezo) ceramic 4a described later, an electromotive voltage 10 times or more can be generated, and if the weak current activator 1 of the present invention is composed of the piezoelectric (piezo) film 4b, the area can be reduced. The thickness is 28 μm, 52 μm, and 110 μm, which are very thin and not bulky. The treatment effect can be obtained by fitting to the body surface. Here, the electrodes 5 provided on the piezoelectric film 4b may be provided on both the upper and lower surfaces of the piezoelectric film 4b as shown in FIG. 18C. The electrode 5 may be provided only on the upper surface of the film 4b, and the conductivity may be improved between the conductive portion 6 provided in close contact with the lower surface of the piezoelectric (piezo) film 4b. If the electrodes 5 are provided on both the upper surface and the lower surface of the piezoelectric (piezo) film 4b, the conductive portion 6 provided in close contact with the electrode 5 on the lower surface, and the conductive state with the conductive sheet 6c and the conductive portion 6B described later are further increased. It can be configured and implemented well. Further, an annular insulating film may be attached around the piezoelectric (piezo) film 4b so that the portion is insulated between the electrode 5 provided on the upper surface and the conductive portion 6. Here, the electrode 5 can be formed by coating a metal material. Examples of the coating method include a sputtering method using a nickel copper alloy, a silver silk screen printing method, and an aluminum vapor deposition method. The conductive portion 6 formed on the glove 1A can be formed by forming the glove 1A with a special conductive fiber or an organic fiber made of acrylic and nylon fiber, and a conductive rubber material or a conductive material on the palm side of the glove 1A. The urethane foam may be formed in a flat and thin shape.

  FIG. 2 shows the configuration shown in FIG. 1 in which a plurality of conductive protrusions 6a, 6a... 6a are provided on the palm side of the glove 1A. If it is this structure, the irritation | stimulation effect of the press by each convex part 6a will be given, and the electroconductivity from each convex part 6a contact | abutted to skin will become good, and it will become easy to flow a weak electric current. Each convex part 6a to be formed can be formed of a conductive rubber material and welded or pasted.

  FIG. 3 shows a configuration in which a conductive portion 6A and a conductive portion 6B formed of a conductive rubber material are provided on the palm side of the glove 1A. As shown in FIG. 3 (c), a conductive sheet 6c made of an aluminum foil material is pasted on the palm side of the glove 1A, and a piezoelectric film 4b is provided on the conductive sheet 6c, and a donut shape is provided on the piezoelectric film 4b. A flat and thin insulating sheet 2 formed of a resin material is stacked, and a conductive portion 6A and a conductive portion 6B made of a conductive rubber material are stacked and pasted as shown in the figure. In this configuration, the electrode 5 provided on the upper surface of the piezoelectric film 4b comes into contact with the conductive portion 6B from the opening portion of the insulating sheet 2 and becomes conductive, and the conductive sheet 6c is an electrode provided on the lower surface of the piezoelectric film 4b. 5 and the conductive portion 6A are brought into contact with each other and become conductive. Therefore, when pressure or an external force is applied to the piezoelectric film 4b to cause bending or distortion, the weak current generated in the piezoelectric film 4b is energized from the conductive portion 6A and the conductive portion 6B into the skin tissue of the skin that is in contact. The conductive portion 6A and the conductive portion 6B formed of conductive rubber are more conductive than the conductive portion 6 made of carbon material impregnated in the gloves 1A of the previous embodiment, and the weak electric current generated is efficiently skinned. It can be energized into the organization. The conductive portion 6A and the conductive portion 6B configured here can be formed with a foil-like copper foil material or an aluminum foil material, or formed with a conductive material such as carbon or a conductive plastic in addition to the conductive rubber. It may be configured.

  FIG. 4 shows a configuration in which convex portions 6a and convex portions 6b are respectively formed on the surfaces of the conductive portions 6A and 6B having the configuration shown in FIG. If it is this structure, the stimulus effect of the press by each convex part 6a and the convex part 6b will be added, and it will become easy to flow weak electric current from each convex part 6a and convex part 6b which contact | abut to skin, and the weak electric current which generate | occur | produced will be generated. It is possible to efficiently energize the skin tissue of the skin.

  FIG. 5 shows that the conductive portion 6 is formed on one surface of the engaging means 10 having an appropriate size, and the electrode 5 on the lower surface of the piezoelectric film 4b is attached on the surface so as to be conductive. The weak current activation tool 1 is configured by providing a hook-and-loop fastener (registered trademark: Velcro) 10a on the back surface. This weak current activation tool 1 of the present invention can be engaged with a commercially available glove 13, and can be implemented in the same manner as the embodiment shown in FIG. If it is this structure, it can attach or detach to the separate glove 13, and when the glove 13 becomes dirty, the glove 13 can be removed from the weak current activation tool 1 of the present invention and washed.

  6 shows the weak current of the present invention in which the conductive sheet 6c, the piezoelectric film 4b, the insulating sheet 2, the conductive part 6A, and the conductive part 6B shown in FIG. 3 are provided on the engaging means 10 shown in FIG. The active tool 1 is constituted. If it is this structure, it can attach or detach to the commercially available glove 13 similarly to the previous example, and when the glove 13 becomes dirty, the glove 13 can be removed from the weak current activation tool 1 and washed. In addition, it is better that the surface of the commercially available gloves 13 is easy to attach, and for example, the gloves 13 made of 50% polyester and 50% nylon can be used.

  FIG. 7 shows that the conductive portion 6A, the piezoelectric film 4b, the insulating sheet 2, and the conductive portion 6B are provided in the glove 1A so that the convex portion 6a formed on the conductive portion 6A and the convex portion 6b formed on the conductive portion 6B. It is configured to project from openings 1a, 1a,... 1a formed on the palm side of glove 1A. If it is this structure, the electroconductive part 6 which touches skin will become only each front-end | tip part of the convex part 6a and the convex part 6b, and it becomes easy to conduct electricity more efficiently and can be implemented similarly.

3, 4, 6, and 7, the electrode 5 is provided on the upper surface of the piezoelectric film 4 b, but the electrode 5 is not provided on the upper surface and is provided in close contact with the upper surface of the piezoelectric film 4 b. The conductivity may be improved between the conductive portion 6B (or the conductive portion 6A).
4-7, the convex part 6a and the convex part 6b are formed as the electroconductive part 6 contact | abutted to a skin surface, and when it hits on a scalp surface by the structure, the convex part is directly from between hairs. The tip portions of the portion 6a and the convex portion 6b can be brought into contact with the scalp surface, and the weak current generated by the configuration can be more effectively energized into the skin tissue of the scalp.

  FIG. 8 shows a configuration in which a weak current generated between a pair of gloves 1A and 1A is passed. A pair of gloves 1A and the entire glove 1A are formed with a conductive conductive part 6 in the same manner as in the previous embodiment, and the piezoelectric film 4b is connected to the inside of one glove 1A and the electrode 5 on the upper surface thereof is electrically connected to the conductive part 6. The conductive sheet 6c that is electrically connected to the lower surface electrode 5 is provided, the conductive wire 6d is connected to the conductive sheet 6c, and both the gloves 1A and the gloves 1A are connected. With this configuration, the left glove 1A and the right glove 1A have different polarities, and pressure and an external force are applied to the left glove 1A, so that the piezoelectric film 4b bends and distorts, so that the conductive surface 6 contacts each glove 1A and glove 1A. The weak electric current generated between the skin tissues can be energized. The conductive wire 6d that connects both gloves 1A and 1A may be connected or disconnected.

  9 and 10 show a configuration in which a metal sheet 7 and a metal sheet 8 of dissimilar metals are provided on the glove 1A, and a weak current is applied to the skin tissue using the action of ionization tendency.

  In FIG. 9, a conductive pair 6 is formed on the entire pair of gloves 1A and 1A as in the previous embodiment, and a metal sheet 7 made of aluminum foil is pasted on the surface of one glove 1A. A metal sheet 8 made of copper foil is pasted on the surface of one glove 1A, conductive sheets 6c are connected to both metal sheets 7 and 8, and conductive wires 6d are connected to both conductive sheets 6c and 6c. It is a thing. When both the gloves 1A and the gloves 1A are brought into contact with the skin surface in this configuration, a closed circuit is formed between the gloves 1A and 1A and the skin, so that the ionization tendency is different between the metal sheet 7 and the metal sheet 8. In addition, an electromotive current is generated by the action of ionization tendency, and a weak current can be passed between the metal sheet 7 and the skin tissue in contact with the metal sheet 8.

  In FIG. 10, a metal sheet 7 made of aluminum foil is attached to the upper part of the surface of each glove 1A, and a metal sheet 8 made of copper foil is attached to the lower part of the surface of the glove 1A. 8 are connected by a conductive sheet 6c. With this configuration, a closed circuit is similarly formed between the skins in contact with the metal surfaces of both metal sheets 7 and 8, and a weak current can be passed through the skin tissue in contact with the metal sheets 7 and 8. . 9 and 10, each metal sheet 7 and metal sheet 8 are provided in the glove 1A, and conductive portions 6 and 6 are formed on the glove 1A so as to be electrically connected to each metal sheet 7 and the metal sheet 8. You may comprise. Alternatively, the conductive sheet 6c may be configured such that the end portion of the metal sheet 7 (or the metal sheet 8) is extended to form a portion of the conductive sheet 6c and contact each other. As the ionization tendency, if the metals with a low ionization tendency are arranged in order, gold → silver → copper → lead → nickel → iron → zinc → aluminum → titanium → magnesium → sodium, of which versatile and conductive It is preferable to form the metal sheet 7 and the metal sheet 8 with a combination of any two of good copper, aluminum, and titanium. Moreover, 1 A of gloves of each Example shown in FIGS. 1-10 can be comprised and comprised with raw materials, such as polyester, nylon, an acryl, cotton, silk, hemp. 1, 2, and 5, a conductive member that protects the piezoelectric film 4 b is provided on the surface of the electrode 5 on the upper surface of the exposed piezoelectric film 4 b, and the electrode 5 contacts the member. It may be configured to energize in the tissue of the skin facing, and that configuration is also included in the configuration of the present invention.

  12 to 14 show a configuration in which the weak current activation tool 1 of the present invention is implemented in the hitting tool 1B. In the configurations shown in FIGS. 12 and 13, the piezoelectric shown in FIGS. 18 (a) and 18 (b). It consists of a body 4.

In FIG. 12, FIG. 12 (a) shows a disassembled configuration of the present invention, in which a large and small opening 1a is formed in a lid 1b provided with a handle 1f held by a hand as shown in the figure. A fitting portion 1c for fitting with the lid 1b is provided, a threaded portion 1d is formed on the side peripheral surface of the fitting portion 1c, and an elastic portion 1e made of urethane foam is provided inside the fitting portion 1c. Yes. In this configuration, the threaded portion 1d is screwed into the lid 1b, and the substrate 3 provided integrally with the electrode 5 and the piezoelectric body 4 is loosely fitted on the surface of the elastic portion 1e. A conductive portion 6A made of a conductive rubber material and a doughnut-shaped conductive portion 6B are superimposed on the surface of the substrate 3 as shown in the figure, and the conductive portion 6A is exposed on the surface of the electrode 5 and the conductive portion 6B is exposed on the surface of the substrate 3 The hitting tool 1B according to the present embodiment is configured by mounting on each of them and screwing the fitting portion 1c into the lid 1b from above. FIG. 12B shows a state in which the fitting portion 1c is screwed into the lid 1b from the state shown in FIG. 12A, and FIG. 12C shows a sectional view of the configuration. ing. When the handle portion 1f is held by hand in the configuration of this embodiment and the scalp surface is struck as shown in FIG. 15, convex portions 6a and convex portions formed in a hemispherical shape on the conductive portion 6A and the conductive portion 6B. The tip of 6b collides with the scalp surface, and at the same time, the substrate 3 is slightly bent inward by the impact force. Therefore, the piezoelectric body 4 provided on the substrate 3 bends following the strain and generates a strain. Generate current. A weak electromotive force can be applied to the skin tissue that is in contact with the convex portion 6 a energized from the electrode 5 and the convex portion 6 b energized from the substrate 3. In this hitting tool 1B, the convex surface 6a and the convex portion 6b are not particularly provided, and the body surface is hit by the surface of the planar conductive portion 6A and the conductive portion 6B, and is weak in the skin tissue contacting from the site. You may comprise so that an electromotive current may be supplied.
As the configuration of the substrate 3 provided integrally with the electrode 5 and the piezoelectric body 4 in this configuration, the substrate 3 is formed of a brass plate having a thickness of about 0.07 mm and a diameter of 50 mm as an example, and the upper surface of the substrate 3 is formed. A piezoelectric body 4 having a thickness of about 0.06 mm and a diameter of 25 mm is provided at the center, and an electrode 5 made of silver is provided on the entire upper surface of the piezoelectric body 4 by thick film printing (silk screen printing) to a thickness of several tens of microns. it can. If the substrate 3 is made of metal, it can be implemented with 42 ALLOY made of brass, aluminum, copper, or alloy with an appropriate thickness and elasticity, and the substrate 3 is vapor-deposited on its surface with a thin plastic material. It may be formed or formed by forming a conductive carbon film or the like. Further, the entire substrate 3 may be formed of a conductive rubber or a conductive plastic material. The thickness of the substrate 3 may be a thickness that is appropriately bent and has elasticity, and when formed by a metal plate, as an example, it may be 0.5 to 0.3 mm or less and 0.1 mm or less. Further, since the substrate 3 and the electrode 5 are slightly separated from each other, the area of the electrode 5 provided on the upper surface of the piezoelectric body 4 may be slightly reduced. When the piezoelectric body 4 is composed of a piezoelectric (piezo) ceramic 4a, in addition to lead zirconate titanate (PZT), barium titanate (BaTiO ₃ ), lead titanate, lead niobate, lithium niobate, etc. are sintered. In the case of the piezoelectric film 4b, the film can be made of polyvinylidene fluoride (PVDF) or the like. By applying pressure to any substance, electric polarization occurs in the substance and an electromotive current is generated.
In the present embodiment, a light emitting diode LED 9 is provided so that the occurrence of an electromotive current can be confirmed by turning on the LED 9. The LED 9 is connected to the conductive portion 6A and the conductive portion 6B so as to be electrically connected to each other. When the scalp surface is hit with the hitting tool 1B, the substrate 3 provided therein is bent, and the piezoelectric body 4 follows the bending. The LED 9 can be configured to be lit by an electromotive current that is generated. With the configuration of this embodiment, it can be confirmed by the lighting of the LED 9 that treatment is actually performed while generating an electromotive current. In addition, you may implement by providing LED9 also in the structure of each Example of this invention. Further, the conductive portion 6A and the conductive portion 6B may be formed of a metal such as an aluminum material or a copper material in addition to the conductive rubber material.

  FIG. 13 shows a configuration of the lid 1b and the fitting portion 1c shown in FIG. 12, in which a striking portion 1g that moves by inertial force is provided in the fitting portion 1c. As shown in the figure, the striking portion 1g is formed of an aluminum material. When the handle 1f of the striking tool 1B of this embodiment is held by hand as shown in FIG. Strikes the surface of the substrate 3 and generates an electromotive current because the impact causes a strain that compresses the piezoelectric body 4 shown in FIG. As in the previous embodiment, a weak electromotive force can be applied to the skin tissue in contact with the convex portion 6a that conducts with the electrode 5 and the convex portion 6b that conducts with the substrate 3. In addition, in the structure shown in FIG. 12, FIG. 13, you may comprise and implement so that it may have the whole cover body 1b without providing the handle | pattern part 1f in particular.

  FIG. 14 shows the configuration of another embodiment of the hitting tool 1B of the present invention. In the configuration of the hitting tool 1B, a flexible handle portion 1f is provided, and the piezoelectric film 4b body shown in FIG. 18 (d) is provided in the handle portion 1f. As shown in FIG. 18 (d), the piezoelectric film 4b is encapsulated with a flexible resin material 11, and the electrodes 5 and 5 provided on the upper and lower surfaces of the piezoelectric film 4b are electrically connected to the electrode terminals 5a and 5a. Is made to protrude. With this configuration, the encapsulating piezoelectric film 4b can be in a moisture-proof state, and even when a strong impact is applied, the piezoelectric film 4b is protected by the resin material 11, and thus is not damaged. If the scalp surface is struck as shown in FIG. 15 in the configuration of the present embodiment, the handle portion 1f is flexible because it is flexible during the transition from FIG. 14 (c) to FIG. The piezoelectric film 4b provided on the substrate also follows and bends, and an electromotive force is generated due to the bending and strain, thereby generating a weak current. In the configuration of the present embodiment, a large number of pin-like convex portions 6a and convex portions 6b that are energized from the electrode terminals 5a and 5a are provided on the lid body 1b. The tip portions of the convex portions 6a and the convex portions 6b can be brought into contact with each other for energization. In addition, the hitting tool 1B of the present invention can be treated by hitting not only the scalp surface but also each part of the face and body. As in the previous embodiment, in this hitting tool 1B, the convex surface 6a and the convex portion 6b are not particularly provided, and the surface of the body is hit by the surfaces of the planar conductive portion 6A and the conductive portion 6B, and comes into contact with the portion. You may comprise so that a weak electromotive force may be sent in skin tissue.

  FIG. 16 shows an embodiment in which the present invention is configured on a face mask 1C. A face mask 1C to be placed on the face is formed with openings 1a at both eyes, nose and mouth as shown in the figure, and band portions 1h and 1h are provided at both ends of the face mask 1C. In FIG. 16A, locking portions 1i and 1i that lock each other are provided at both ends of the band portions 1h and 1h, and the locking portions 1i and 1i formed of hook-and-loop fasteners (registered trademark: Velcro) are connected to each other. The face mask 1C can be attached to the face by being locked. In FIG. 16B, the band portions 1h and 1h are formed by expanding and contracting bands, and the face mask 1C can be attached to the face by covering the band portions 1h and 1h on the head. In the configuration of this embodiment, when the face mask 1C is attached to the face, the band portions 1h and 1h are provided so that the piezoelectric film 4b body shown in FIG. 18 (d) just contacts the temple portion. Then, as shown in the figure, the conductive portion 6A and the conductive portion 6B are provided on the inner surface of the face mask 1C, and the electrode terminals 5a and 5a electrically connected to the electrodes 5 and 5 of the piezoelectric film 4b are connected to the conductive portion 6A by the conductive sheet 6c. Each conductive portion 6B is connected to each other. When the face mask 1C having this structure is mounted on the face and the mouth is moved by talking or eating, the temple part that comes into contact with the piezoelectric film 4b always moves and causes ups and downs. The piezoelectric film 4b in contact with the piezoelectric film 4b is appropriately bent and distorted to generate a weak electromotive current. A weak current flows from the surfaces of the conductive portion 6A and the conductive portion 6B provided on the inner surface of the face mask 1C into the skin tissue that contacts the forehead and cheeks of the face. With the configuration of the present invention, if the face mask 1C is worn on the face in daily life, the skin can be activated and treated by the weak current that is generated, and there is also a whitening effect. The face mask 1C can be formed by using, for example, a material made of 80% cotton and 20% polyester. The conductive portion 6A and the conductive portion 6B provided on the inner surface of the face mask 1C are made of a foil-like metal (such as aluminum foil or titanium foil). ) Or a flat thin conductive rubber material.

  FIG. 17 shows an embodiment in which the present invention is configured as a hair net 1D. As shown in FIGS. 17 (a) and 17 (b), a band 1h is provided at the lower end of the hair net 1D covering the head, and both ends of the band 1h are locked to each other with hook-and-loop fasteners (registered trademark: Velcro). Locking portions 1i and 1i are provided. By engaging the locking portions 1i and 1i with each other, the hair net 1D can be firmly fixed to the head, and the hair net 1D is put on the head as shown in FIG. Similarly to the example, the piezoelectric film 4b body shown in FIG. 18D is provided on both side surfaces so as to be in contact with the temple portion. Inside the hair net 1D, a large number of convex portions 6a and convex portions 6b that are electrically connected to the electrode terminals 5a and 5a are provided at appropriate intervals. In this configuration, as shown in FIG. 17 (f), when the mouth is moved by talking or eating with the hair net 1D covered on the head, the temple part always moves and causes ups and downs. The piezoelectric film 4b in contact with the portion is appropriately bent to cause distortion and generate a weak electromotive current. And the weak electric current which generate | occur | produced into the skin tissue flows from the convex part 6a and the convex part 6b which are contact | abutting to the scalp surface. As another configuration of the embodiment, the hair net 1D may be configured in a lattice shape as shown in FIG. 17 (c), and the grid can be obtained by covering the hair net 1D according to the configuration with the head down. A bundle of hairs can be taken out from each gap and attached, and the tips of the many convex portions 6a and 6b provided inside the hair net 1D can be directly brought into contact with the scalp surface. Further, as shown in FIG. 17 (d), a plurality of patterned sub-hair nets 1D may be prepared and configured so that they can be attached to the inside of the main hair net 1D by appropriately provided locking portions 1i. . Further, as shown in FIG. 17 (e), a hair net 1D is provided with a lever 1j, and even if the undulation on the skin 12 is slightly applied by applying the lever principle, the movement is amplified to bend the piezoelectric film 4b. You may comprise. In addition, in the configuration shown in FIGS. 16 and 17, one of the locking portions 1i may be formed in a horizontally long shape so that the locking position can be changed and mounted. Further, the piezoelectric film 4b may be provided at an appropriate position other than the position where it comes into contact with the temple as in this embodiment.

  The above-described gloves 1A and hitting tool 1B of the present invention can also apply a weak current stimulus to a diseased site, activate the cells at that site by the generated weak current, and increase the natural healing power. It is possible to alleviate the pain and cure the pain at that site. Weak current treatment was originally used by athletes and professional athletes to treat bruises and ligament damage, and it was known that Beckham, the representative of the World Cup England, took into the treatment of fractures and treated them in a short period of time. The invention can also be implemented for treatment. In addition, you may select the amount of weak electric currents which generate | occur | produce and energize appropriately by setting suitably the magnitude | size and thickness of the piezoelectric material 4 and the piezoelectric film 4b which are comprised by this invention.

(A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention (A) Front view of one embodiment of the present invention (b) Front view of one embodiment of the present invention and an exploded longitudinal sectional view thereof in the XY direction (c) Front view disassembled into each component of the present invention Front view of one embodiment of the present invention Front view of one embodiment of the present invention Front view of one embodiment of the present invention Front view of the present invention (A) Perspective view disassembled into components of one embodiment of the present invention (b) Perspective view of one embodiment of the present invention (c) Longitudinal sectional view of one embodiment of the present invention (A) Perspective view of one embodiment of the present invention (b) (c) Longitudinal sectional view of one embodiment of the present invention (A) Front view of one embodiment of the present invention (b) (c) Side view of one embodiment of the present invention Front view of the present invention (A) (b) Front view of one embodiment of the present invention (A) Perspective view of one embodiment of the present invention (b) Front view of one embodiment of the present invention (c) Perspective view of one embodiment of the present invention (d) Longitudinal sectional view of one embodiment of the present invention ( e) Side view of one embodiment of the present invention (f) Side view of the embodiment of the present invention (A) Side view of the configuration of one embodiment of the present invention (b) Front view of the configuration of one embodiment of the present invention (c) Side view of the configuration of one embodiment of the present invention (d) One embodiment of the present invention Front view of example configuration (A) (b) Side view showing the electromotive principle of the present invention

Explanation of symbols

1: weak current activation tool 1A: glove 1B (of weak current activation tool): hitting tool 1C (of weak current activation tool): face mask 1D (of weak current activation tool): hair net 1a (of weak current activation tool) : Opening portion 1b: Lid 1c: Fitting portion 1d: Screwed portion 1e: Elastic portion 1f: Handle portion 1g: Striking portion 1h: Band portion 1i: Locking portion 1j: Lever portion 2: Insulating sheet 3: Substrate 4 : Piezoelectric body 4a: Piezoelectric ceramic 4b: Piezoelectric film 5: Electrode 5a: Electrode terminal 6: Conductive part 6A: Conductive part 6B: Conductive part 6a (different from conductive part 6A): (Conductive part) Convex part 6b (on 6 and 6A): Convex part 6c (on conductive part 6B): Conductive sheet 6d: Conductive wire 7: Metal sheet 8: Metal sheet 9 (different from 7): LED
10: engaging means 10a: hook-and-loop fastener (registered trademark: Velcro)
11: Resin material 12: Skin 13: Gloves (separate from the engagement means)

Claims (16)

In a glove that fits and fits in a hand, the glove is placed in a hand and the palm is brought into contact with the body surface such as the face or scalp and pressure is applied to the part where pressure is applied . A piezoelectric body (4) that generates electricity by strain and an electrode (5) are provided on the upper surface of the piezoelectric body (4), and electricity generated by the piezoelectric body (4) is applied to at least the flat surface of the glove. The conductive part (6) that contacts the body surface is provided, and the pressure applied to the glove is applied by applying pressure by bringing the palm side into contact with the body surface while the glove is fitted and attached to the hand. The weak current generated by the deformation of the compression and bending distortion generated in the piezoelectric body (4) by the pressure applied to the piezoelectric body (4) provided on the glove is supplied from the piezoelectric body (4). In the tissue on the surface of the body abutting from the surface of the conductive portion (6) and the surface of the electrode (5) provided on the piezoelectric body (4) To form a closed circuit, a weak current active instrument of energizing the weak current to electromotive the body surface thereof stimulation as added without power in piezoelectric body (4). In a glove that fits and fits in a hand, the glove is placed in a hand and the palm is brought into contact with the body surface such as the face or scalp and pressure is applied to the part where pressure is applied . A conductive portion (6: 6A) is provided, which is provided with a piezoelectric body (4) that generates electromotive force by strain, and further energizes electricity generated by the piezoelectric body (4) to the palm and palm of the glove. ) And a conductive part (6: 6B), and the glove is fitted to the hand and the pressure is applied by bringing the palm side into contact with the body surface to follow the pressure applied to the glove. A weak current that is generated by deformation of compression or bending distortion generated in the piezoelectric body (4) by the pressure applied to the piezoelectric body (4) provided on the piezoelectric body (4) is provided on the flat surface of the finger that is energized from the piezoelectric body (4). The structure of the body surface that comes into contact with the conductive part (6: 6A) and the conductive part (6: 6B) provided on the palm of the hand To form a closed circuit, a weak current active instrument of energizing the weak current to electromotive the body surface thereof stimulation as added without power in piezoelectric body (4). Engaging means (8) detachably engaged with the palm side of a glove to be fitted and attached to the hand, the engaging means (8) being engaged with the palm side of the glove and engaged with the glove The piezoelectric body (4) and the piezoelectric body, which are caused by compression or bending distortion when the pressure is applied to a portion of the engaging means (8) that is brought into contact with the body surface such as the face or scalp to apply the pressure. An electrode (5) is provided on the upper surface of (4), and electricity generated by the piezoelectric body (4) is applied to at least the flat part of the finger of the engaging means (8) to contact the body surface. Pressure applied to the glove by providing a conductive portion (6), putting the glove in the hand and engaging the engaging means (8), and applying pressure by bringing the palm side of the glove into contact with the body surface in the pressure applied to the piezoelectric element (4) provided on the engagement fastening means (8) to follow the electromotive by deformation of the strain of the piezoelectric body (4) occurring compression and bending Closed circuit in the tissue of the surface of the body abutting from the surface of the conductive portion (6) energized from the piezoelectric body (4) and the surface of the electrode (5) provided on the piezoelectric body (4). A weak current activation tool in which a weak current generated by the piezoelectric body (4) is applied to the body surface and the stimulus is applied without a power source. Engaging means (8) detachably engaged with the palm side of a glove to be fitted and attached to the hand, the engaging means (8) being engaged with the palm side of the glove and engaged with the glove A piezoelectric body (4) that generates electricity by compressing or bending distortion when the pressure is applied to a portion of the engaging means (8) that is in contact with the body surface such as the face or scalp, A conductive portion (6: 6A) and a conductive portion (6: 6B) are made to apply electricity generated by the piezoelectric body (4) to the finger and palm portions of the engaging means (8) to contact the surface of the body. ), And with the glove fitted on the hand and the engaging means (8) engaged, the pressure applied to the glove is followed by applying pressure by bringing the palm side of the glove into contact with the body surface. in the pressure applied to the piezoelectric body provided on the engagement fastening means (8) (4), weak current to electromotive by the deformation of the strain of the resulting compression or bending the piezoelectric member (4) In the tissue on the surface of the body that comes into contact with the conductive portion (6: 6A) provided on the palm portion of the finger and the conductive portion (6: 6B) provided on the palm portion that are energized from the piezoelectric body (4). A weak current activator which forms a closed circuit, applies a weak current generated by the piezoelectric body (4) to the body surface, and applies the stimulus without a power source. In a pair of gloves to be fitted and attached to the hand, each of the conductive parts (6) is provided on the palm side of the pair of gloves to be brought into contact with the body surface such as the face or scalp, and at least one of the gloves of the glove is attached. the palm side is fitted to the hand portion abutted so the pressure is applied to the body surface, the piezoelectric body electromotive in compressive strain and bending in that the pressure is applied to (4) is provided, in the pair of gloves A conductive wire (6d) for energizing the electromotive force generated by the piezoelectric body (4) is provided therebetween, and with the pair of gloves fitted and attached to the hand, the palm side is brought into contact with the body surface for pressure. Is applied to the piezoelectric body (4) provided on at least one glove following the pressure applied to the glove, and is weakly generated by deformation of the compression or bending distortion generated in the piezoelectric body (4). The surface of the conductive portion (6) provided on one glove that is energized from the piezoelectric body (4), and the front A closed circuit is formed in the tissue on the surface of the body in contact with the surface of the conductive portion (6) provided on the other glove that is energized via the conductive wire (6d), and the piezoelectric body (4) generates electricity. A weak current active device that applies a weak current to the body surface and applies the stimulus without a power source. In the hitting tool which is held by hand and hits the body surface, the piezoelectric body (4) is provided on the elastic portion (1e) so as to overlap with the impact surface by hitting the body surface of the hitting tool. A conductive portion (6: 6A) and a conductive portion (6: 6B) for energizing electricity generated by the piezoelectric body (4) in contact with the conductive body and projecting by holding the hitting tool by hand. By hitting the body surface with the surface of the part (6: 6A) and the conductive part (6: 6B), the elastic part (1e) and the piezoelectric body (4) provided thereon are pressed according to the impact force. When the force is applied and the elastic part (1e) is deformed by the pressing force, the compression or bending of the piezoelectric body (4) provided on the elastic part (1e) following the deformation is superimposed. The body surface that abuts from the surface of the conductive part (6: 6A) and the conductive part (6: 6B) through which a weak current generated by strain is passed from the piezoelectric body (4) Forming a closed circuit in the tissue, the piezoelectric body (4) weak current active tool irritation thereof by energizing a weak current to electromotive the body surface was so added without power in the compression and bending of. A weak current activation device that applies a weak current generated in the body to the body surface and applies the stimulus without a power source. In the hitting tool for hitting the body surface, there is provided a piezoelectric body (4) that generates electricity when pressure is applied to the hitting tool, and a hitting part (1g) that hits the piezoelectric body (4) by hitting the body surface. Further, a conductive portion (6: 6A) and a conductive portion (6: 6B) that are energized from the piezoelectric body (4) are provided, and the surface of the piezoelectric body (4) is struck by holding the hitting tool in the hand and hitting the body surface. The weak current generated by the compressive strain generated by the pressure applied from the striking portion (1 g) to the conductive portion (6: 6A) and the conductive portion (6: 6B) or from the conductive portion (6: 6A) A closed circuit is formed in the tissue on the surface of the body abutting from the projecting part (6: 6a) and the projecting part (6: 6b) conducting to the conductive part (6: 6B), and the piezoelectric body (4) A weak current active device that applies a weak current generated by compression to the body surface and applies the stimulus without a power source. In the hitting tool for hitting the body surface, a handle portion (1f) that is appropriately bent is provided on the hitting tool, a piezoelectric film (4: 4b) that is appropriately bent is provided on the handle portion (1f), and the piezoelectric film ( The piezoelectric film (4: 4b) is provided by providing a conductive part (6: 6A) and a conductive part (6: 6B) to be energized from 4: 4b) and hitting the body surface with the handle (1f) in hand. A convex current (6: 6A) or a weak current generated by bending strain caused by the pressure applied to the conductive portion (6: 6A) or from the surface of the conductive portion (6: 6B) or the conductive portion (6: 6A) : 6a) and a weak part that generates electromotive force by forming a closed circuit in the tissue on the surface of the body that abuts from the convex part (6: 6b) that conducts to the conductive part (6: 6B), and bending the piezoelectric body (4) A faint current activation tool that applies current to the body surface and applies the stimulus without a power source. In a face mask that is detachably mounted in close contact with the face surface, a band-shaped band part (1h) having an appropriate width for fastening around the head is fixed to the face mask, and the band part (1h) A piezoelectric body (4) is provided at a portion that abuts the head of the head, and a conductive portion (6: 6A) that is in close contact with the face surface on the inner surface of the face mask and energizes electricity generated by the piezoelectric body (4) And the conductive portion (6: 6B), and the band portion (1h) is fastened around the head portion, fixed and mounted, and the band portion is moved by the movement of the head portion contacting the inner surface of the band portion (1h). Following the compression or bending force applied to (1h), a weak current generated by compression or bending distortion generated in the piezoelectric body (4) provided in the band (1h) is supplied to the piezoelectric body (4). From the surface of the conductive portion (6: 6A) and the conductive portion (6: 6B) energized from above Forming a closed circuit in the tissues of the body surface, the piezoelectric body (4) weak current active instrument of energizing the weak current to electromotive the body surface thereof stimulation as added without power in the compression and bending of. In a face mask that is fixedly attached to a face surface and fixedly attached, a piezoelectric film (4: 4b) is formed on an inner surface of the face mask that is in close contact with the face surface, and an electrode (5) is formed on an upper surface of the piezoelectric film (4: 4b). In addition, a conductive portion (6) is provided on the inner surface of the face mask so as to be in close contact with the face surface and energize the electricity generated by the piezoelectric body (4), and the face mask is fixed in close contact with the face surface. In this state, following the force that bends the face mask applied by the movement of the face surface that is in contact with the inner surface of the face mask, an electromotive force is generated by bending distortion generated in the piezoelectric film (4: 4b) provided on the face mask. A closed circuit is formed in the skin tissue of the face abutting from the surface of the electrode (5) and the conductive portion (6) through which a weak current is passed from the piezoelectric film (4: 4b), and the piezoelectric film (4: 4b) 4b) A weak current generated by bending is applied to the body surface. Energized weak current active device which is adapted added without power irritation thereof. In the hair net that is detachably attached to the head, a band-shaped band portion (1h) having an appropriate width to be fastened and fixed around the head is provided on the hair net, and the band is touched to the head of the band portion (1h). A plurality of convex portions (6: 6a) and a plurality of convex portions that are provided with a piezoelectric body (4) in contact with the scalp surface and further energize electricity generated by the piezoelectric body (4). (6: 6b) is a band that is applied by the movement of the head that abuts against the inner surface of the band portion (1h) in a state in which the band portion (1h) is fastened and fixed around the head. Following the force that compresses or bends the portion (1h), the weak current generated by the compression or bending strain generated in the piezoelectric body (4) provided in the band portion (1h) The plurality of projections (6: 6a) and the plurality of projections (6: 6b) that are energized from the front end are in contact with each other A weak current active device in which a closed circuit is formed in the structure of the scalp, and a weak current generated by compression or bending of the piezoelectric film (4: 4b) is applied to the body surface and the stimulation is applied without a power source. . The weak current activation tool according to any one of claims 1 to 7, 9, and 11, wherein the piezoelectric body (4) is formed of a piezoelectric film (4b) that is bent to generate electricity. The piezoelectric body (4) is a piezoelectric body (4) provided on the surface of a substrate (3) having appropriate flexibility and conductivity, and bends following the bending of the substrate (3). The weak current activation tool according to any one of claims 1 to 7, 9, and 11, comprising a piezoelectric body (4) to be electrified. 14. The weak current activator according to claim 13, wherein the piezoelectric body (4) is made of a piezoelectric ceramic (4a) having an appropriate bending thickness. The weak current activation tool according to any one of claims 1 to 12, wherein in the piezoelectric body (4), electrodes (5) are provided on an upper surface and a lower surface of the piezoelectric body (4). LED (9) is provided in the said weak electric current active tool, The weak electric current generated by the deformation | transformation of the distortion produced by the force added to a piezoelectric material (4) can be confirmed now by lighting of LED (9). 15. The weak current activation tool according to any one of 15 above.

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