JPH11123226A - Aesthetic probe using pure titanium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To activate metabolism in a skin cell, and promote a beautiful face, a beautiful skin and a beautiful fair complexion by using a probe head which uses titanium and is constituted of a specific dimension. SOLUTION: A probe head diametrical dimension K of a probe head B using titanium is set to 60 mm, and a vibrator sticking margin diametrical dimension of a vibrator sticking margin F is set to 46.4 mm, and a probe head total height dimension T is set to 18 mm, and a probe head side surface thickness dimension is set to 6.8 mm, and a probe head skin contact surface thickness dimension is set to 8 mm, and a vibrator diameterical dimension of a ceramic vibrator C is set to 40 mm. The above dimensions are assembled, and are formed as a probe main body, and the built-in ceramic vibrator C is vibrated by offering sine wave vibration through a lead wire D. A slight fever is also generated by intensity of vibration and electric output of the ceramic vibrator C, and becomes a heat source of the probe head B, and a temperature of a probe head skin contact surface G is kept at 40 deg.C to 45 deg.C slightly higher than a body temperature, and comfortableness is increased.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to the fields of beauty, hairdressing, esthetics, and general therapy.
By using pure titanium steel, skin disharmony such as metal allergy and atopic dermatitis is adjusted, the body is adjusted, and the whole body beauty technology is provided based on excellent antibacterial safety. It is.

[0002]

2. Description of the Related Art Titanium (hereinafter referred to as titanium) is a metal element of Group IV of the periodic table. In 1790, Gregger of England discovered its existence as an element.

[0003] Titanium has a small specific gravity, about 1/2 that of copper, and about 2/3 that of steel. Its strength is comparable to steel, its corrosion resistance is superior to stainless steel, and it has excellent properties such as excellent heat resistance. .

[0004] It accounts for 0.44% of the earth's crustal composition, and is the ninth of all elements, and is the second largest in practical metals, after iron, aluminum and magnesium.

Although it has been used for a long time as a white pigment in the form of titanium oxide, its use as a simple metal was made after World War II, and the scientific formula was Ti, formula weight 47.90, specific gravity 4.50.
(20 ° C.) Melting point 1800 ° C. Boiling point> 3000 ° C.

[0006] The ores include rutile TiO ₂ and ilmenite FeO.TiO _{2. In} Japan, titanium slag from which the iron component of ilmenite (including titanium sand iron) in the Tohoku region and the like is refined and imported gilded red stone is refined. Raw materials.

[0007] In the refining, carbon is added to the raw material by a chlor method developed in the United States, heated by chlorine in a chlorination furnace to form liquid titanium tetrachloride, refined to remove impurities,
Reduction with sodium or magnesium in a vacuum reduction furnace,
Make titanium sponge.

[0008] The material obtained by compressing the material into a rod shape is arc-melted in a vacuum as an electrode, formed into an ingot, and processed into a plate, a rod, a tube or the like by rolling, extrusion, or the like.

Since titanium is light and strong, it is also used in jet engine materials, missile parts, and supersonic body materials.

[0010] Further, since it is excellent in corrosion resistance, it plays an important role as a material for chemical industrial equipment such as distillation towers, reaction towers and valves.

Titanium production began in the United States in 1948, and production in Japan began in 1952. It rapidly developed as a material for jet engines, and the current industrial production is in the United States, Russia, and Japan. Great Britain 196
Production has started on a trial basis for five years.

As described above, titanium is a metal that has been relatively long discovered, but has not been used in practical use for about 150 years before the refining method was discovered by Dr. Kroll in the United States.

However, once the refining technology has been established, it has been prized for practical use because of its light, strong, and rust-resistant properties, and has begun to be used as an important material mainly for heavy industry.

[0014]

It has been elucidated that titanium has various properties, and it has been confirmed that it is a metal that is indispensable in modern society. The antibacterial properties of titanium have become a hot topic, as well as being light, strong and rust resistant.

Further, the high-performance antibacterial titanium used in the present invention is a newly developed antibacterial titanium alloy. By controlling the composition and oxidizing the surface, the photocatalytic reaction is dramatically improved, and the antibacterial property is improved. In addition, it also has effects such as deodorization and antifouling.

In recent years, there is staphylococcus as a bacterium for which antibacterial measures are required. Staphylococci are found in purulent and wounded skin, in severely rough areas of the skin and in the nasal passages, and are usually killed by heat or antibiotics, but the toxins (enterotoxins) produced by staphylococci affect the human body .

In the case of infection with staphylococci, it was possible to treat with an antibiotic called methicillin. However, strong staphylococci, which methicillin does not show any effect, occur. I'm calling

[0018] MRSA is M (a kind of methicillin / antibiotic) R (resistant / opposing) SA (Staphylococcus staphylococcus), a bacterium which is regarded as a very serious problem as a hospital infection. .

The present inventor pays attention to the weather resistance and antibacterial property of titanium, and considers the time when it is necessary to take measures against bacterial infection not only in hospital infection but also in beauty and hairdressing as well as in aesthetic fields. With this in mind, the present invention has been made.

[0020]

[Means for Solving the Problems] The aesthetic industry has developed in recent years and has been adopted in the fields of beauty and barber, and the demand is becoming widespread as a general therapy industry in everyday society.

[0021] Also, ultrasonic waves of 1 MHz and 2 MHz are touched. Ultrasound of this wavelength has been used in the past, and these technologies are permeating the industry.However, since the probe head using stainless steel is forming the mainstream, its function is fully used. Did not show up.

However, it is believed that the use of the biowave probe head according to the present invention can further enhance the effect of the therapy.

The general beauty industry, including esthetics,
Conventionally, this industry has been created mainly for beautiful face, beautiful skin, whitening, slimming, etc., but the beauty and esthetic industry in recent years has focused on the whole body beauty, including the face.

[0024] These are comprehensive therapies, and by adding a beauty and prevention technology from Chinese medicine to the biowave technology, it is possible to eliminate stress of modern people,
It is designed to enhance the overall relaxation effect and seek the beauty of both body and mind.

Here, the biowave will be briefly described, but prior to that, an explanation of technical terms will be given.

Synapse is a gap between nerves (a gap between nerves). Usually, a neurotransmitter is secreted and connected.

Tetanus stimulus = Two kinds of sine waves of 1 MHz and 2 MHz applied to a nerve synapse.

LTP effect = excitation state induced in nerve cells by tetanus stimulation (long-term potentiation effect).

The function of the biowave is to activate the metabolism of skin cells by the stimulation of tetanus. When the probe is in contact with the skin while the probe is switched on, 1 MHz or 2 MHz ultrasonic waves emitted from the built-in vibrator are provided. Stimulates the synapses of peripheral nerves distributed at a depth of about 2 mm under the epidermis.

Stimulation of peripheral nerve synapses causes an LTP effect, which excites peripheral nerve cells, thereby increasing the bioactivity of the skin cell area controlled by the peripheral nerve by a factor of 4-5.

As a result, rejuvenation of the skin is promoted, the stickiness of the makeup is improved, and the effect of restoring the bare skin that has been tired from the makeup is exerted.

By receiving biowave stimulation,
Sinusoidal waves flow through a multi-aqueous layer having a water-retaining effect in the skin cells, particularly in a portion called connective tissue in the dermis layer, thereby regulating the flow of body fluids and promoting the metabolic activation of the cells.

An essential element in such cosmetics and aesthetics is a biowave probe, which stimulates peripheral nerve synapses in the skin cell region and the dermis layer to remove old keratin. It is used to facilitate the removal of internal and external waste products.

The probe is used not only for massage of the face but also for rubbing and softening all parts of the body such as the abdomen, upper arms and thighs, soothing and removing old dead skin. Therefore, most use stainless steel.

In recent years, beauty and aesthetics have been shown from all kinds of data to show not only the effects on beautiful faces and beautiful skin, but also the release of stress and the enhancement of comprehensive relaxation effects. It is even beginning to be used in medical treatment areas such as Cairo and Shiatsu.

However, most of the above-mentioned probe parts are made of stainless steel, so that
There are adverse effects such as inability to use for people who react sensitively to metals.

The inventor of the present invention has improved the efficiency of the aesthetic itself by using the characteristics of titanium, which is light, strong, rust-free, and having good thermal conductivity, and the antibacterial property that has been recently recognized, for the probe head. To develop a probe that can be used by everyone.

[0038]

Embodiment 1 A probe head diameter dimension K of a probe head B using titanium steel is set to 60 mm, and a transducer attachment diameter F of a transducer attachment allowance F is set to 46.4 mm.

The total height T of the probe head is 18 mm, the thickness N of the probe head side surface is 6.8 mm, the thickness S of the probe head skin contact surface is 8 mm, and the diameter M of the vibrator of the ceramic vibrator C is 40 mm.

By assembling the above into a probe main body A and providing a sine wave vibration via a lead wire D, the built-in ceramic vibrator C vibrates. It generates two types of ultrasonic vibration of 2 MHz.

Due to the vibration of the ceramic vibrator C and the strength of the electric output, slight heat is generated, a heat source for the probe head B is required, and the temperature of the probe head skin contact surface G is set to 40 ° C. to 45 ° C. slightly higher than the body temperature. Keep at ℃ and amplify comfort.

[0042]

Embodiment 2 The probe head B made of titanium steel has a probe head diameter K of 55 mm, and a vibrator pasting allowance F of the vibrator pasting allowance F has a diameter L of 41.4 mm.

The total height T of the probe head is 18 mm, the thickness N of the probe head side surface is 6.8 mm, the thickness S of the probe head skin contact surface is 8 mm, and the diameter M of the ceramic vibrator C is 35 mm.

By assembling the above into a probe main body A and providing a sine wave vibration via the lead wire D, the built-in ceramic vibrator C vibrates. It generates two types of ultrasonic vibration of 2 MHz.

The vibration of the ceramic vibrator C and the strength of the electrical output generate weak heat, and a heat source for the probe head B is required. The temperature of the probe head skin contact surface G is set to 40 ° C. to 45 ° C. slightly higher than the body temperature. Keep at ℃ and amplify comfort.

[0046]

Embodiment 3 The probe head diameter dimension K of the probe head B using titanium steel is set to 50 mm, and the transducer attachment allowance F of the transducer attachment allowance F is set to 36.4 mm.

The total height T of the probe head is 18 mm, the thickness N of the probe head side surface is 6.8 mm, the thickness S of the probe head skin contact surface is 8 mm, and the diameter M of the ceramic vibrator C is 30 mm.

By assembling the above into a probe main body A and providing a sine wave vibration via a lead wire D, the built-in ceramic vibrator C vibrates. It generates two types of ultrasonic vibration of 2 MHz.

Due to the vibration of the ceramic vibrator C and the strength of the electric output, slight heat is generated, a heat source for the probe head B is required, and the temperature of the probe head skin contact surface G is set to 40 ° C. to 45 ° C. slightly higher than the body temperature. Keep at ℃ and amplify comfort.

[0050]

Embodiment 4 The probe head B made of titanium steel has a probe head diameter dimension K of 45 mm, and a transducer attachment allowance F has a transducer attachment allowance diameter L of 31.4 mm.

The total height T of the probe head is 18 mm, the thickness N of the probe head side surface is 6.8 mm, the thickness S of the probe head skin contact surface is 8 mm, and the diameter M of the vibrator of the ceramic vibrator C is 25 mm.

By assembling the above into a probe main body A and providing a sine wave vibration through the lead wire D, the built-in ceramic vibrator C vibrates. It generates two types of ultrasonic vibration of 2 MHz.

The vibration of the ceramic vibrator C and the strength of the electrical output generate weak heat, and a heat source for the probe head B is required. The temperature of the probe head skin contact surface G is set to 40 ° C. to 45 ° C. slightly higher than the body temperature. Keep at ℃ and amplify comfort.

[0054]

Fifth Embodiment A probe head B made of titanium steel has a probe head diameter K of 40 mm, and a vibrator pasting allowance F of a vibrator pasting allowance F has a diameter L of 26.4 mm.

The total height T of the probe head is 18 mm, the thickness N of the probe head side surface is 6.8 mm, the thickness S of the probe head skin contact surface is 8 mm, and the diameter M of the ceramic vibrator C is 20 mm.

By assembling the above into a probe main body A and providing a sine wave vibration via a lead wire D, the built-in ceramic vibrator C vibrates. It generates two types of ultrasonic vibration of 2 MHz.

The vibration of the ceramic vibrator C and the strength of the electrical output generate weak heat, and a heat source for the probe head B is required. The temperature of the probe head skin contact surface G is set at 40 ° C. to 45 ° C. slightly higher than the body temperature. Keep at ℃ and amplify comfort.

The temperature of the probe head skin contact surface was set to 40.
The reason why it was made flexible from ℃ to 45 ℃ is that some errors occur due to seasonal temperature differences, room temperature differences, air conditioner on / off, and also depending on the type and nature of the gel (emulsion serum). A temperature difference occurs.

Therefore, the temperature of the skin contact surface G is set to 38 ° C. depending on the type of the ceramic vibrator C and the strength of vibration and electric output.
It is also necessary to have the option of changing the temperature to about 48 ° C.

[0060]

According to the present invention, the use of a biowave probe head using pure titanium as a main material promotes the metabolic activation of skin cells, particularly the portion called connective tissue in the epidermis and dermis. By the thing, a beautiful face of the whole body,
Promotes comprehensive beauty effects such as skin whitening, whitening and antiallergic effects.

Further, by stimulating peripheral nerve synapses, stress can be eliminated and a comprehensive relaxation effect can be promoted. New technology could be provided.

Furthermore, due to the excellent antibacterial action of titanium, it is possible to take measures against bacterial infection in public facilities, which is a problem in recent years, so that it is possible to provide a cleaner and safer beauty technique. It became something.

[Brief description of the drawings]

FIG. 1 is a side view of a probe main body.

FIG. 2 is a sectional view showing a combination of probe heads.

FIG. 3 is a cross-sectional view showing dimensions of a main part of the probe head.

FIG. 4 is an XX plan view showing the main part dimensions of the probe head.

FIG. 5 is an XX plan view showing a combination of probe heads.

[Explanation of symbols]

 A Probe body B Probe head C Ceramic vibrator D Lead wire E Internal screw of probe head F Vibrator sticking allowance G Probe head skin contact surface K Probe head diameter L L Vibrator sticking allowance diameter M Vibrator diameter N Probe Head side thickness dimension S Probe head skin contact surface thickness dimension T Probe head overall height X Arrow indicating plane

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tachiko Takahashi 3-3-1 Miyagaoka, Chuo-ku, Sapporo, Hokkaido Inside Prism Rela (72) Inventor Masako Hoshina Miyagaoka, Chuo-ku, Sapporo, Hokkaido 3-3-1, Prism Rira Co., Ltd.

Claims (5)

[Claims] 1. A probe head B made of titanium steel has a probe head diameter K of 60 mm, and a transducer attachment allowance F of a transducer attachment allowance F has a diameter L of 46.4 mm. By setting the probe head total height T to 18 mm, the probe head side surface thickness N to 6.8 mm, and the probe head skin contact surface thickness S to 8 mm, the vibrator diameter M of the ceramic vibrator C is set to 44 mm to 36 mm. , Configured probe body A. 2. The probe head B made of titanium steel has a probe head diameter K of 55 mm, and a transducer attachment allowance F has a transducer attachment allowance diameter L of 41.4 mm. By setting the probe head total height T to 18 mm, the probe head side surface thickness N to 6.8 mm, and the probe head skin contact surface thickness S to 8 mm, the vibrator diameter M of the ceramic vibrator C is set to 38 mm to 32 mm. , Configured probe body A. 3. The probe head B made of titanium steel has a probe head diameter K of 50 mm, and a transducer attachment allowance F of a transducer attachment allowance F has a diameter L of 36.4 mm. By setting the probe head total height T to 18 mm, the probe head side surface thickness N to 6.8 mm, and the probe head skin contact surface thickness S to 8 mm, the vibrator diameter M of the ceramic vibrator C becomes 32 mm to 28 mm. , Configured probe body A. 4. The probe head B made of titanium steel has a probe head diameter K of 45 mm, and a transducer attachment allowance F has a transducer attachment allowance diameter L of 31.4 mm. By setting the probe head total height T to 18 mm, the probe head side surface thickness N to 6.8 mm, and the probe head skin contact surface thickness S to 8 mm, the vibrator diameter M of the ceramic vibrator C is 27 mm to 23 mm. , Configured probe body A. 5. A probe head B made of titanium steel has a probe head diameter K of 40 mm, and a transducer attachment allowance F has a transducer attachment allowance diameter L of 26.4 mm. By setting the probe head total height T to 18 mm, the probe head side surface thickness N to 6.8 mm, and the probe head skin contact surface thickness S to 8 mm, the vibrator diameter M of the ceramic vibrator C becomes 22 mm to 18 mm. , Configured probe body A.