JPH03236859A - Ceramic ion-effect element and its manufacture and ceramic ion-effect therapeutic instrument using this element and its manufacture - Google Patents

Abstract

PURPOSE:To obtain a ceramic ion effect element which can easily manufactured from a low cost material and which will not be affected by magnetism by molding a mixture of at least two kinds of transition metal oxide powder of Mn, Co, Ni, etc., into small grains, and sintering the grains to form a sintered body, and constituting the ceramic ion-effect element of the sintered body. CONSTITUTION:A ceramic ion effect element comprises a sintered body formed by molding a mixture of at least two kinds of transition metal oxide powder of Mn, Co, Ni, etc., into small grains, and sintering the grains. The ion effect element of the ceramic ion effect element made from transition metal oxide of Mn, Co, Ni, etc., is made to abut on a therapeutic point in a shoulder being stiffened, etc., and held thereto and then each kind of oxides is ionized by electrolyte of sweat, etc., discharged from capillaries existing in skin surface and emits electrons and a very small amount of electrons are dissolved in muscle fibrils inside the skin surface. The potential of cells is varied and stimulus is transmitted to next cell bodies through an axis-cylinder and electric stimuli run through cells in sequence and thereby various cells expand and contract and blood circulation is activated and cells inside the shoulder being stiffened or a bruised portion, etc., are activated.

Description

Detailed Description of the Invention [Objective of the Invention] (Industrial Application Field) The present invention is used by being attached to acupuncture points, channels, or painful areas on the skin surface of the human body or other animals, and is used mainly to treat stiff shoulders, stiff shoulders, etc. The present invention relates to a ceramic ion effect device effective in alleviating or curing shoulder pain, back pain, muscle pain, sensitivity to cold, etc., a method for manufacturing the same, a ceramic ion effect treatment device using this device, and a method for manufacturing the same.

(Prior Art) Conventionally, as a treatment device mainly aimed at reducing or curing stiff shoulders, shoulder pain, lower back pain, muscle pain, sensitivity to cold, etc., a disc-shaped magnet body with a diameter of 3 mm to 5 m is attached to an adhesive tape or an adhesive pad. It is known that it is used by pasting it on acupuncture points, meridians, or painful areas on the surface of the human skin.

(Problem to be solved by the invention) However, since conventional products use magnets, material costs are high, production costs are high, processing is difficult, and shapes cannot be determined easily. Furthermore, as more and more people carry magnetic cards, there is a problem that magnets have an adverse effect on these cards.

SUMMARY OF THE INVENTION In view of the above-mentioned problems, an object of the present invention is to provide a ceramic ion effect device and a method for manufacturing the same, which are inexpensive in material cost, easy to manufacture, and free from the adverse effects of magnetism, and a ceramic ion effect treatment device and a method for manufacturing the same. be.

[Structure of the invention]

(Means for Solving the Problems) The ceramic ion effect element according to claim 1 of the present invention is obtained by forming a mixture of at least two kinds of transition metal oxide powders such as Mn5Co and Ni into small particles and sintering them. It is made of a sintered body.

The method for manufacturing a ceramic ion effect element according to claim 2 of the present invention is to pressure-form a fine powder obtained by mixing, calcining, and pulverizing at least two types of transition metal oxide powders such as Mn5Co and N1 using a dry press. A small granular molded body is obtained, and then this molded body is fired at 1100° C. to 1400° C. to form a sintered body.

The method for manufacturing a ceramic ion effect element according to claim 3 of the present invention is to improve plasticity by adding an organic binder to a fine powder obtained by mixing, calcining, and pulverizing at least two kinds of transition metal oxide powders such as Mn5CoSNi. The plastic material is then molded into small granules of any shape to obtain a small granular molded body, and then the small granular molded body is fired at 1100° C. to 1400° C. to form a sintered body.

The ceramic ion effect therapy device according to claim 4 of the present invention is a ceramic ion effect therapy device made of a sintered body obtained by forming a mixture of at least two kinds of transition metal oxide powders such as Mn5Co and Ni into small particles and sintering them. It consists of an element and an adhesive piece that abuts and holds the element on the surface to be adhered.

The method for manufacturing a ceramic ion effect therapy device according to claim 5 of the present invention comprises mixing, calcining and pulverizing fine powder of at least two transition metal oxide powders such as Mn, Co1Ni, etc., and press-molding the fine powder using a dry press. A small granular molded body is obtained, and then this molded body is fired at 1100° C. to 1400° C. to form a sintered body, and this sintered body is held by an adhesive piece.

The method for manufacturing a ceramic ion effect therapy device according to claim 6 of the present invention includes adding an organic binder to a fine powder obtained by mixing, calcining, and pulverizing at least two kinds of transition metal oxide powders such as Mn, Co, and Ni. The plastic material is added to impart plasticity, and this plastic material is formed into small particles of any shape to form a small granular molded body, and then this small granular molded body is fired at 1100°C to 1400°C to form a sintered body. , this sintered body is held by an adhesive piece.

(effect) The ceramic ion effect element of the present invention is made of Mn.

When an ion effect element made of a transition metal oxide such as Co or Ni is held in contact with the back (pathway) of a stiff shoulder area,
Electrolytes such as sweat discharged from capillaries existing on the skin surface cause each oxide to become Mn2L → Mn”+
3e Co20. →Co"+ 3e NizOl →Ni"+ 3e, ionizes and releases electrons, and these electrons dissolve in minute amounts into myofibrils within the skin surface. The dissolved electrons are
Na is the outermost constituent of muscle cell bodies on the skin surface.
It acts on sodium ions (sodium ions) and increases the action potential of this ion.Then, in order to lower the potential, the cell sends out the potassium ions inside the cells and takes in N1. This change in potential is transmitted to the axons that make up nerve cells via transmitters. This axon transmits the electrical excitation to the next cell body. In this cell body, it acts again on the outermost N1, changing the potential of this cell. The impulse is transmitted to the next cell body through the axon. In this way, electrical stimulation passes through the nerve cells in sequence. The various cells then expand and contract, activating blood circulation and cells in areas such as stiff shoulders and bruises.

Furthermore, since the metal oxide is sintered at high temperature to form a ceramic, it emits far infrared rays of 7 to 30 microns when warmed by body temperature, further activating cells.

Further, the method for manufacturing the ceramic ion effect element of the present invention includes:
By calcining the transition metal oxide powder, water and air contained in the metal oxide are removed, increasing the density, which is then dry pressed into small particles and then heated at 1100°C to 14°C.
The metal oxide is made into a ceramic by firing at 00°C to form a sintered body. If the sintering temperature is below 1,100°C, it is insufficient to form a ceramic, and if it is above 1,400°C, it will melt and be unable to maintain its shape.

In addition, an organic binder is added to the pulverized transition metal oxide powder to give it plasticity, and this plastic material is molded into small particles of any shape and then the molded body is sintered at high temperature to remove the organic binder. A sintered body made of the removed transition metal oxide in the desired shape is obtained.

Further, in the ceramic ion effect treatment device of the present invention, the ceramic ion effect element is held on the surface to be adhered by an adhesive piece, so that the ceramic ion effect of the element is reliably applied to the surface to be adhered.

(Example) An embodiment of the product of the present invention will be described with reference to the accompanying drawings.

1 is 1-φ to 40 mmφ made of transition metal oxide sintered body
This is a small-grain ceramic ion effect element whose shape is spherical, disc-shaped, square, polygonal, star-shaped, heart-shaped, etc., or one or both sides of these flat parts are formed into a protruding shape, or a small protrusion is formed. For example, as shown in Fig. 3, small protrusions 2, 2 are formed on both sides, or as shown in Fig. 4, one side is formed into a pyramid-shaped sharp part 3, or a As shown in the figure, small protrusions 2a are formed on the entire surface, and the contact area of these elements 1 with the skin is:
It is 1ma+2 to 1000W2.

4 is an adhesive piece coated with adhesive on one side, and its shape is circular, triangular, square, oval, elongated rectangular, star-shaped, heart-shaped, etc., and the material is cloth, paper, textile, rubber. , synthetic resin, and a composite material thereof, and an adhesive is applied to the adhesive surface. The area of these adhesive pieces 4 is 1offI
In2 to 5000wn2.

Then, one ion effect element 1 or a plurality of ion effect elements 1 are attached at appropriate intervals as necessary to this adhesive surface, and a release paper 5 is attached from the upper surface. It is convenient if both sides of the element 1 have the same shape, since it can be attached to the adhesive piece 4 in either direction.

When using, peel off the release paper 5 and attach the ion effect element 1.
Apply the adhesive strip 4 to the skin of the affected area such as stiff shoulders.
By pasting and fixing it, the ion effect of the ion effect element 1 activates cells and promotes blood circulation. Further, the ion effect element 1 made of ceramic emits far infrared rays using body temperature as a heat source to promote cell activation.

Next, the present invention will be explained in detail.

Manufacturing method example 1 (1) As transition metal oxides, Mn2O3; 40-60 parts by weight, preferably 40 parts by weight, Co2O3; 30-2
0 parts by weight, preferably 30 parts by weight, N1□03; 30~
20 parts by weight, preferably 30 parts by weight (in addition to C.
At least one of rzOi, CuO, Fe, 04, and Fe20i may be added. ).

(2) This mixture of transition metal oxides was heated to 600°C in the atmosphere.
20 minutes to 2 hours at ~900°C, preferably 4 hours at 800°C
Bake for 0 minutes to remove moisture and air. Remove from the oven and bring to room temperature.

(3) Next, the calcined powder was placed in a pot mill with ethanol, ground for 5 hours, and then passed through Me-Sauche to a particle size of 1
Obtain oxide fine powder of 0#m or less.

(4) The obtained fine powder was dry pressed to approximately 500 kg.
Molding is carried out at a pressure of g/cor to 1000 kg/ci to obtain small granular compacts with a diameter of 1 mm to 40 mm.

(5) Next, the ceramic ion effect element 1 is obtained by sintering the small granular molded body at 1100°C to 1400°C.

(6) Next, place the ion effect element 1 on the adhesive piece 4 coated with adhesive, and paste the release paper 5 on the adhesive side.
Obtain the product shown in the figure.

Manufacturing method example 2 The steps (1) to (3) are the same as in Production Example 1.

(4) To 100 parts of the obtained fine powder, add an organic binder consisting of 30 parts by weight of an organic vehicle and 4 parts by weight of a plasticizer solution, each of the following formulation.

organic vehicle Ethyl cellulose 15% by weight Polyvinyl butyral 85% by weight plasticizer solution Polyethylene glycol 60% by weight Phthalate ester 40% by weight Then, the mixture is kneaded with a kneader to obtain a plastic material.

(5) Next, the plastic material is extruded into a sheet having a thickness of 1 mm using an extruder.

(6) The sheet-like extrusion molded product is press-molded to obtain a small granular molded product having a predetermined shape.

(7) After drying the small granular molded body, 1100°C to 1400°C
Bake for 2 hours. The organic binder is removed by firing, and the ion effect element 1 made of a sintered body of transition metal oxide is obtained.

The subsequent manufacturing method is the same as Manufacturing Method Example 1.

Manufacturing method example 3 This was the same as manufacturing method example 2, but a plastic material was injection molded to obtain a small granular molded body.

The other methods are the same as those in Production Example 2.

〔Effect of the invention〕

According to the present invention, by contacting the acupuncture points, channels, or painful areas on the skin surface of the human body or other animals with the ceramic ion effect element, cells in the human body etc. are activated, blood circulation is promoted, and mainly stiff shoulders, stiff shoulders, etc. It can reduce and cure shoulder pain, lower back pain, muscle pain, sensitivity to cold, etc.

Further, the transition metal oxide made into a ceramic by sintering emits far infrared rays using body temperature as a heat source, thereby further promoting the ion therapy effect.

Furthermore, since the ion effect element does not generate magnetism, there is no problem in carrying a magnetic card.

Moreover, the ionic effect is further increased by blending two or more types of transition metal oxides.

[Brief explanation of drawings]

FIG. 1 is a front view showing one embodiment of the ion effect treatment device of the present invention, FIG. 2 is a plan view of the same, and FIGS. 3 to 5 are front views showing different embodiments of the ion effect device. be. 1. Ceramic ion effect element, 4. Adhesive piece. 405-

Claims (6)

[Claims] (1) A ceramic ion effect element comprising a sintered body obtained by forming a mixture of at least two types of transition metal oxide powders such as Mn, Co, and Ni into small particles and sintering them. (2) At least two kinds of transition metal oxide powders such as Mo, Co, and Ni are mixed, calcined, and crushed into fine powders, which are pressure-molded using a dry press to form small granular compacts, and then this compact is A method for manufacturing a ceramic ion effect element, comprising firing at 1100°C to 1400°C to form a sintered body. (3) At least two types of transition metal oxide powders such as Mn, Co, and Ni are mixed, calcined, and ground, and an organic binder is added to the fine powder to give it plasticity. 1. A method for manufacturing a ceramic ion effect element, which comprises molding into a granular form to obtain a small granular compact, and then firing the small granular compact at 1100° C. to 1400° C. to obtain a sintered body. (4) A ceramic ion effect element made of a sintered body obtained by molding a mixture of at least two kinds of transition metal oxide powders such as Mn, Co, and Ni into small particles and sintering this element to a surface to be adhered. A ceramic ion effect treatment device characterized by comprising an adhesive piece that is applied and held. (5) At least two kinds of transition metal oxide powders such as Mn, Co, Ni, etc. are mixed, calcined, and pulverized, and the fine powder is pressure-molded using a dry press to form a small granular compact, and then this compact is Firing at 1100°C to 1400°C to form a sintered body,
A method for manufacturing a ceramic ion effect treatment device, which comprises holding this sintered body in an adhesive piece. (6) At least two kinds of transition metal oxide powders such as Mn, Co, and Ni are mixed, calcined, and ground, and an organic binder is added to the fine powder to give it plasticity. The method is characterized in that it is formed into granules to form a small granular molded body, and then the small granular molded body is fired at 1100°C to 1400°C to form a sintered body, and this sintered body is held by an adhesive piece. A method for manufacturing a ceramic ion effect treatment device.