WO2006112462A1 - Musical instrument - Google Patents

Abstract

A musical instrument having a substance, which obtained by blending microparticles of a natural mineral such as graphite-silica emitting far-infrared radiation or minus ions with various coatings, applied and/or deposited in a definite part of the instrument body. Since this instrument can emit the far-infrared radiation or minus ions by itself or in the tone range thereof during musical performance, it can soothe the heart of the musician or listeners around her/him. At the same time, attempts are made to improve the physiological effects of the far-infrared radiation or minus ions on the human body to thereby enhance natural healing ability and preventive effects against diseases.

Description

 Specification

 Musical instrument

 Technical field

 [0001] The present invention relates to a novel invention in which general painting techniques for various musical instruments are improved.

 Background art

 In the invention of such a field, for example, a mark attached to a keyboard musical instrument has been made for the purpose of surely preventing the occurrence of corrosion and wrinkles over time.

 It is a keyboard lid mark of a keyboard instrument provided on the back of the keyboard lid on which a paint film is formed, and has a predetermined shape that constitutes a powerful keyboard mark and is embedded in the paint film on the back of the keyboard lid. It has a mark screw made of metal and a transparent coating film that is coated on the surface and exposed to the outside. (See Patent Document 1)

 [0003] In addition, as a recent improvement of the mouthpiece, a mouthpiece has been devised that is light in weight and can produce a timbre that is different from the conventional one. This mouthpiece is made of, for example, titanium or a titanium alloy, or a certain zirco-umium or zirco-umium alloy, so that the mouthpiece has excellent water absorption and light weight, which is light and cannot be crushed. Can also provide a musical instrument with a good weight balance, and can produce a different tone from a conventional mouthpiece made of brass. As a result, it is possible to increase discrimination from other performers. (See Patent Document 2)

 [0004] However, any of these kinds of inventions is a technology that simply improves the durability of the product itself and the means of preventing rustling. There was no invention that could create an atmosphere where performance was possible.

 [0005] Patent Document 1: Japanese Patent Laid-Open No. 2001-92445

 Patent Document 2: JP-A-5-127665

 Disclosure of the invention

 Problems to be solved by the invention

[0006] Therefore, the present invention is in the musical instrument itself or in the sound range played by the musical instrument, and softens the performer's or listener's mind by listening to powerful performances at or near the performer. V. In terms of words, it is designed to be played in an atmosphere that makes you feel relaxed.

 Means for solving the problem

 The main feature of the present invention is that each instrument itself is coated with a natural ore that emits far-infrared rays and negative ions, such as natural graphite silica (commonly known as black silica), and emits far-infrared rays. It was found that the above-mentioned purpose was achieved by adding the action of emitting negative ions and the result of repeated experiments, and such natural ore materials such as graphite silica were used for the resonance part of the instrument or the entire instrument. .

 [0008] Ions are small substances that are charged with electricity, and their size is called lZlOOOmm. They are fine particles that cannot be seen with the naked eye or even with a general microscope. And there are two kinds of these very small substances, those with positive electricity (positive ions) and those with negative electricity (negative ions), which are connected to each other to make various substances. .

 [0009] And in addition to maintaining life through the metabolism of cells, humans have the function of ingesting ions that exist in nature through respiration, and the ingested ions are transported to cells and pass through the cell membrane. Ion exchange takes place.

 This ion exchange is a system that releases intracellular waste products and carbon dioxide and takes in necessary oxygen and nutrients. The power of the body depends greatly on the balance of ions. In many ways, it has created a lot of positive ions and an environment.

 [0010] Specifically, the exhaust gas that automobiles disperse every day is a representative example, and this is the best way to increase the plusion. In addition, various types of smoke emitted from factories, polluted rivers and acid rain, dioxin produced during incineration of garbage, agricultural chemicals, various food additives (chemicals), and toxic new building material adhesives (Formaldehyde), other organic phosphorous compounds used in daily necessities, and the kind of radiation emitted from the end of the universe are the main sources of positive ions.

[0011] Furthermore, the ultraviolet rays that are poured from the destroyed ozone layer are also a major factor for producing positive ions. In addition, TVs and TVs that have rapidly spread over the past few decades “Electromagnetic waves” emitted from various electric and electronic equipment such as data and microwave ovens are also a group of positive ions. Due to these multi-layered effects, negative ions are drastically reduced, and positive ion exposure is conspicuous. A lot of atmospheric environment was created, and in this way the ion balance in the air collapsed in a short time.

 [0012] Under such circumstances, air with a lot of negative ions neutralizes human body oxides to be alkaline, making it easier for cells to absorb oxygen and nutrients. The force also makes it easier to discharge waste products and activates the cells. In other words, it has the effect of improving the natural healing power of human beings, as well as improving the physiological effects of the human body.

 [0013] The main effects of negative ions on the environment are, specifically, cleansing of air pollution caused by scientific 'electrical' radioactive materials, new building materials, etc. Purify toxic substances (formaldehyde), etc., decompose cigarette smoke and unpleasant smells !, prevent deodorization, and prevent air pollution caused by bactericidal action (carcasses of ticks) Prevention of mold, removal of odor, prevention of small pests (infestation of termites), and promotion of potted plant growth.

 [0014] Furthermore, negative ions activate human tissues to excrete acidic substances (toxins) in the body's cells, change to alkaline to increase blood circulation, activate cells, It has outstanding effects on biological functions such as purification, allergy improvement, and analgesia.

 [0015] That is, as the effect of negative ions on the human body, blood vessels are dilated, blood pressure becomes normal, blood tends to be alkaline, and bones become strong. In addition, diuretic action is promoted, breathing is reduced and eased, pulse is reduced, fatigue recovery is promoted, autonomic nervous function is sedated, growth is promoted and improved, and so on. It's a good thing to send.

[0016] In order to better understand, the negative ion effect taking "sleep" as an example is described. By accepting powerful negative ions into the body (being in an atmosphere of negative ions), the oxidized body Will be reduced and your mood will be calm. In addition, the calming effect rests the excited nerves and makes you sleep well. And of course, a good night's sleep can help relieve stress and help the parasympathetic activity. [0017] In order to achieve the above-mentioned object, the means of the present invention is to provide a substance obtained by mixing natural ore such as natural graphite silica that emits far-infrared rays and negative ions into thermosetting resin. It is characterized in that it is applied and Z or vapor-deposited on a specified part of the instrument body.

 [0018] As a result, as described above, for example, the spirit of the performer of the instrument is stabilized, and calming and happiness is enhanced by powerful negative ions. In the brain, beta-1 endorphin acts to stabilize the body and increase immunity.

[0019] In addition, negative ions have an autonomic adjustment function such as insomnia, headache, Zensoku, rheumatism, stiff shoulders, back pain, chronic fatigue, neuralgia, and irritability. The negative anion balances the autonomic nerves, the brain is calmly deposited, the limbs are warm enough to operate the instrument, that is, the healthy body condition of “head cold foot fever” It can be kept and improved.

[0020] At this time, the blood purifying action works, and the action of neutralizing the blood into healthy, weak alkaline healthy blood with resistance.

 In particular, when the coating material of the present invention is used for a musical instrument that is held in the body such as an ukulele or mandolin, or a musical instrument that has a high degree of adhesion to the body, a preventive effect such as a larger blood purification effect can be expected. .

[0021] According to the present invention, when a musical instrument main body sound (sound wave) is generated by applying and Z or vapor-depositing a material that emits such excellent negative ions to a predetermined portion of the musical instrument main body. Negative ions are induced at the same time as the performance due to the vibration of the body or contact with the human body.

 In addition, the inventor of the present application has previously found that natural ores such as graphite silica used in the present invention emit such negative ions and at the same time generate excellent far infrared rays.

[0022] Based on the above knowledge, in the present invention, the natural ore such as graphite silica described above emits far-infrared rays and negative ions around it by giving a little vibration. In view of this, this powder is blended into thermosetting resin and applied to the instrument surface. A material was used.

 The natural ore powder or fine particles such as graphite silica used in the present invention preferably has an average particle size of 10 microns or less. The smaller the average particle size, the greater the effect of far-infrared radiation and negative ion radiation, and the smoother the surface finish when used as a coating on a musical instrument.

 Examples of the natural ore emitting far-infrared rays and negative ions used in the present invention include germanium, radium, tourmaline and the like in addition to graphite silica (black silica).

 Hereinafter, exemplary embodiments of the present invention will be described.

 (1) A musical instrument characterized in that fine particles of graphite silica (black silica) that emits far infrared rays and negative ions are blended in a coating material, and applied to a predetermined part of the musical instrument body and Z or vapor-deposited.

 (2) Fine particles of the above graphite silica (black silica) are 4 to 6% carbon, 0.35 to 0.55% magnesium, 70 to 90% silica, 1.0 to 2.0% titanium, 2% Oxidized iron 0.4 to 0.6%, Na !! Kum 0.06 to 0.1%, Anoleminicum 5 to 8%, Potassium 0.8 to 2.0%, Canorecicum 0.01 to 0. The musical instrument according to (1), which has a component power of 03% and moisture of 0.25 to 0.4%.

 (3) The graphite silica (black silica) fine particles have a far-infrared emissivity of 90-99% at room temperature, and are emitted in the 2 to 18 micron wavelength band called growth light and health light. The musical instrument according to (1) and (2), which is characterized.

 (4) The instrument according to any one of (1) to (3), wherein the size of the fine particles of the graphite silica is 10 microns or less.

 (5) The musical instrument according to any one of (1) to (4), wherein the musical instrument is used while being held in the body.

(6) The musical instrument according to any one of (1) to (5), wherein the musical instrument is used in close contact with a body.

(7) The musical instrument according to any one of (1) to (6), wherein the musical instrument is a ukulele or mandolin.

(8) A musical instrument characterized in that fine particles of natural ore that emit far-infrared rays and negative ions are blended in a paint and applied to a predetermined part of the instrument body and z or vapor-deposited.

(9) The above natural ore fine particles have a far-infrared emissivity of 90-99% at room temperature and grow. The instrument according to (8), characterized by being emitted in a wavelength band of 2 to 18 microns, which is called a light ray or a health ray.

 (10) The musical instrument according to (8) and (9), wherein the natural ore has a size of 10 microns or less.

 (11) The musical instrument according to any one of (8) to (10), wherein the musical instrument is used while being carried in the body.

(12) The musical instrument according to any one of (8) to (11), wherein the musical instrument is used in close contact with a body.

(13) The musical instrument according to any one of (8) to (12), wherein the musical instrument is a ukulele or a mandolin. Brief Description of Drawings

[1] Far-infrared emissivity measurement graph at 35 ° C for a resin board (weight ratio of unsaturated polyester resin and graphite silica powder is 67:33).

[2] Radiation intensity measurement graph of far-infrared rays at 35 ° C for a resin board (weight ratio of unsaturated polyester resin and graphite silica powder is 67:33).

[3] Negative ion transition graph at normal temperature for the same resin board (weight ratio of unsaturated polyester resin and graphite silica powder is 67:33).

 [Fig. 4] Classification of musical instruments.

 [Figure 5] Plan view of the open grand piano.

 FIG. 6 is a partial cross-sectional explanatory view of a vibration member.

 FIG. 7 is a perspective view of an open vertical piano.

 FIG. 8 is a partial cross-sectional explanatory view of a vibration member.

 FIG. 9 is a perspective view of a harp.

[10] Partial cross-sectional explanatory view of the vibration member.

 [Fig. 11] Front view of violin and bow.

12] Partial cross-sectional explanatory view of the vibration member.

 [Fig. 13] Front view of the guitar.

14] Partial cross-sectional explanatory view of the vibration member.

 FIG. 15 is a perspective view of an accordion.

16] Partial cross-sectional explanatory diagram of the vibration member.

[Fig. 17] Perspective view of xylophone. FIG. 18 is an enlarged perspective view of a bar.

 FIG. 19 is a partial cross-sectional explanatory view of a vibration member.

 FIG. 20 is an enlarged perspective view of various drums.

 FIG. 21 is a partial cross-sectional explanatory view of a vibration member.

 FIG. 22 is a perspective view of various wind instruments.

 [Fig. 23] Front view of the ukulele.

 FIG. 24 is a partial cross-sectional explanatory view of a vibration member.

 [Fig.25] Front view of mandolin.

 FIG. 26 is a partial cross-sectional explanatory view of a vibration member.

 BEST MODE FOR CARRYING OUT THE INVENTION

[0024] Hereinafter, the present invention will be specifically described by way of examples using graphite silica as the natural ore used in the present invention and unsaturated polyester resin as the synthetic resin, but the scope of the present invention is not limited thereto. It is not limited to.

 The graphite silica used in the present invention is naturally produced in the mountain town of Hokkaido, and its composition is 4 to 6% carbon, 0.35 to 0.55% magnesium, 70 to 90% silica, Titanium 1.0 to 2.0%, Dibasic iron oxide 0.4 to 0.6%, Sodium 0.06 to 0.1%, Aluminum 5 to 8%, Potassium 0.8 to 2.0% , Calcium 0.01 to 0.03%, moisture 0.25 to 0.4%. In addition, physical and chemical properties are inorganic, weakly acidic (Ph5.5-7.5), nonflammable, water-resistant, abrasion-resistant (hardness 7.0-7.5), high infrared absorption, brittle Have conductivity and conductivity.

 [0025] The means for blending the graphite silica into the synthetic resin is a method in which a powder of graphite silica is kneaded and uniformly dispersed in an unsaturated polyester resin (laminate resin).

 Next, an example of the molding method will be described. A glass plate coated with a release agent is used as a mold, and an unsaturated polyester resin-based gel coat is sprayed on the surface to be cured. After the gel coat is cured, 4 plies of chopped strand mat # 450 are laminated using the above-mentioned laminating resin kneaded with the graphite powder, and heated and cured at 60 ° C. for 2 hours. Then, the mold is removed after cooling at room temperature.

[0026] In the above blending method, the weight of unsaturated polyester resin and graphite silica powder Mixing and kneading each so that the ratio is 67:33 'Far-infrared emissivity and intensity at 35 ° C of the molded resin board (5cm long x 5cm wide x 0.5cm thick) The results of measurements using a measuring device (ION TESTER KST-900, manufactured by Kobe Radio) at the study group (Osaka City) are shown in Figs. As a result, it was confirmed that the resin plate containing graphite silica emits far infrared rays at room temperature.

 Furthermore, in the above blending method, the blended resin kneaded and molded kneaded resin so that the weight ratio of unsaturated polyester resin and graphite silica powder is 67:33 (length 5 cm x width 5 cm x thickness Fig. 3 shows the results of measuring the negative ion transition at room temperature (0.5 cm) using the measurement device (ION TESTER KST-900, manufactured by Kobe Radio) at the Far Infrared Applied Research Group (Osaka City). It is as follows. As a result, it was confirmed that a negative ion was emitted under normal temperature of the resin plate containing graphite silica.

As described above, since the resin of the present invention is blended with graphite silica having a far infrared radiation function at room temperature, far infrared radiation is emitted from the entire resin at room temperature by the far infrared radiation function of graphite silica.

 Therefore, if this resin is used, the effects of far-infrared rays can be easily enjoyed at ordinary temperatures in the general usage of resin products, paints, adhesives and other resins.

 [0028] In Fig. 5 and the following, a compound material (1) made by mixing the natural graphite silica obtained by the present invention and a thermosetting resin is used as the surface or the back surface of the acoustic vibration member of many kinds of musical instrument bodies. In the following, an example of applying with a brush or by means such as a force applied with an instrument such as a spray gun or welding such as electrostatic coating is shown.

In this case, for example, as shown in FIG. 5, when the acoustic vibration member force is accommodated in the musical instrument main body, the musical instrument main body is also an acoustic vibration member. Material (1) will be applied.

The acoustic vibration member shown in this embodiment is applicable to all musical instruments, and the technical category of the present invention includes all these musical instruments.

[0031] As shown in Fig. 4, the classification of musical instruments is based on the bodies of Erich von Hornoostel and Kunor achs, which were announced in 1914. I can know. This “five classification method” classifies musical instruments according to their pronunciation method, and is widely adopted today by musicians internationally. Note that the present invention can also be applied to musical instruments peculiar to Japan such as shamisen and koto that are not included in this classification. Example 1

 [0032] Figure 5 shows typical details of a modern grand piano: (101) hitchpin, (102) bass bridge, (103) soundboard, (104) long bridge, (105) The first string, (106) is the second string, (107) is the third string, (108) is the damper, and (109) is the rest pin.

 [0033] In particular, it is important to apply the composite material (1) obtained by mixing the natural graphite silica obtained by the present invention and the thermosetting resin to the sound board (103). As shown in Fig. 6, the housing (110) of the instrument body is also an acoustic vibration member.

 [0034] Normally, the size of a grand piano is 168 to 178 cm, the size for a guest room or living room is 180 to 210 cm, and the length for a concert is 210 to 270 cm.

 Therefore, during the performance of a piano coated with the compounding material (1), far infrared rays and negative ions are always emitted from the piano body and the surroundings become a sum and a powerful atmosphere, and the performance can be played well. , The listener can enjoy the best feeling.

 [0035] In particular, the Taland piano for concerts has a structure in which the opened lid reflects the sound, and the floor under the soundboard reflects the sound. It is necessary to apply 1), and naturally it is preferable to apply compounding material (1) to the keyboard itself.

 [0036] Fig. 7 shows a vertical piano, which is an example of a one-piece iron frame created by Alpheus Babcock in 1825. (201) is a Chu-Jung pin, (202) is a frame, ( 203) ί bridge, (204) ί three strings, (205) ί two strings, (206) ί one string, (207) is a soft pedal, (208) is a sustain pedal, (209 ) Is a bass string, (210) is a bridge, and (211) is a soundboard.

[0037] In particular, it is important to apply the compounding material (1) of the present invention to the sound board (211). As shown in Fig. 8, the housing (212) of the instrument body is also an acoustic vibration member. From that surface! / It is also important to paint the back.

 Example 3

 [0038] Figure 9 illustrates a harp, especially an orchestra's noop, where (301) is a strut, (302) is a pedestal, (303) is a neck, (304) is a tuning nail, (305) is a disc, (306) is a string, (307) is a sound board, (308) is a pedal, and (309) is a leg.

[0039] In particular, it is important to apply the compounding material (1) of the present invention to the soundboard (307) as shown in Fig. 10, but the support (301) of the harp body is also an acoustic vibration member. Then, you can paint on the front or back.

 Example 4

 [0040] FIG. 11 illustrates a violin, where (401) is a spiral, (402) is a threadhouse, (403) is a thread basket, (404) is a fingerboard, (405) is a string, (406) is a string Sound board, (407) is a piece, (408) is a sound hole, (409) is an E-line regulator (410) is a clasp, (411) is for the jaw, and the following is a bow (412) Is the bow tip, (413) is the bow, (414) is the hair, (415) is the hair clip, and (416) is the side plate.

 [0041] In particular, it is important to apply the compounding material (1) of the present invention to the sound board (406) as shown in FIG. Then paint on the front or back. Especially in the case of a violin, the soul pillar attached under the right leg of the internal piece of the violin transmits vibration to the back plate of the violin, and the power tree is attached to the back of the torso. In particular, it is necessary to apply compounding material (1) to the backside of the violin. Reference numeral (416) denotes a side plate.

 [0042] Furthermore, when applied to the bow (413) and possibly the hair (414), the bow and fingerboard (404) will also radiate far-infrared rays and negative ions from the bow and fingerboard (404). Example 5

 [0043] FIG. 13 shows a guitar. (501) is a machine head, (502) is a thread basket, (503) is a nut, (504) is a fingerboard, (505) is a fret, and (506) is A sound hole, (507) is a sound board, (508) a string, (509) is a piece, and (510) is a side plate.

[0044] In particular, it is important to apply the compounding material (1) of the present invention to the sound board (507) as shown in Fig. 14, but the fingerboard (504) and the like are also acoustic vibration members. Its front or back Paint on the surface. Reference numeral (510) denotes a side plate.

[0045] Guitars are also distinguished as classical guitars and acoustic guitars, and are gaining great popularity all over the world today. It fits well with any music and is light and easy to carry, making it an ideal instrument to use for singing and accompaniment to other instruments as well as solo power. Classic (Spanish) guitars have changed little since the 16th century, but popular acoustic guitars (folk guitars) are now produced in a wide variety of styles. Of these, the present invention can be implemented with any guitar.

 Example 6

 FIG. 15 shows an accordion, where (601) is a bellows, (602) is a keyboard, (603) is a treble register, (604) is a bass register, and (605) is a bus button.

 [0047] A typical button accordion as a modern accordion is a complex with 41 keys, 11 treble registers, master coupler, 120 bus buttons, and 7 bass registers. The small piano keyboard accordion has 25 keys and 12 bass.

 [0048] The present invention can be applied to any accordion. In particular, it is important to apply the compounding material (1) of the present invention to the bellows (601) as shown in FIG. The forceful bellows (601) is always forced to expand and contract repeatedly during its performance, and has the optimum conditions for generating negative ions.

 [0049] In addition to the keyboard (602), the high tone register (603) and the bass register (604), as well as the bass button (605), are desired to be applied.

 Example 7

 [0050] Figure 17 is a xylophone for a modern orchestra, the most well-organized percussion instrument, also called a xylophone or a xylophone. It is equipped with a metal resonance tube (702) under a wooden bar (701), which has a 3 to 4 octave range and plays in various shapes.

[0051] In particular, it is important to apply the compound material (1) of the present invention to the wooden bar (701) and the resonance tube (702) as shown in Figs. Also, if possible, apply it to “bachi” (not shown). The powerful wooden bar (701) and resonance tube (702) always vibrate during the performance. It is carried out repeatedly and has the optimum conditions for generating negative ions. Example 8

 FIG. 20 shows a general type of membrane instrument. Membrane instruments are instruments that produce sound by the vibration of a stretched membrane or skin, and generally refer to drums.

 [0053] There are two basic types of membrane musical instruments, a drum type and a millriton type, and drums are further classified into a cylindrical type, a bowl type, and a frame type depending on the shape. Drums struck by friction are classified as different types, and cylindrical drums are classified according to their shape, such as cylindrical, conical, barrel, and hourglass.

 [0054] Figure 20 is categorized according to the shape of the trunk: a cylinder with a straight side (801), a cone with a tilted side (802), a barrel with a puffed side (803), and There is an hourglass shape (804) with a particularly sophisticated shape.

 [0055] The goblet type (805), the drum with a foot with the foot engraved on the normal drum (806), the long drum (807) with its characteristic length, and light skin There are a number of frames, such as a frame-shaped drum (808) that stretches around the frame. Of these, the present invention can be implemented in any form.

 [0056] In particular, it is important to apply the compounding material (1) of the present invention to the skin (809) and the body (810) stretched on each drum as shown in FIG. Also, if possible, apply it to “bachi” (not shown). The powerful skin (809) and the body (810) are constantly vibrated and resonated during the performance, especially with the optimal conditions for generating negative ions.

 Example 9

 [0057] Fig. 22 shows an example of a metal wind instrument. (901) is a soprano saxophone, (902) is a tenor saxophone, (903) ί funorate, (905) is the head tube, (906) is the main tube, and (907) is the foot tube.

 There are many types of wind instruments, but the present invention can be applied to a variety of instruments.

[0058] If the compounding material (1) of the present invention is described in terms of the entire outer surface of each wind instrument and the flute (903), its mouthpiece (904), head tube (905), main tube (906), foot It must also be applied to the tube (907). Example 10

 FIG. 23 illustrates a ukulele. (1001) is a sound hole, (1002) is a front plate, and (1003) is a side plate.

 In particular, it is important to apply the compounding material (1) of the present invention to an acoustic vibration member such as the above-mentioned front plate (1002) and sound board (1003) as shown in FIG. Incidentally, (1003) is a side plate. Example 11

 FIG. 25 illustrates a mandolin, where (1101) is a sound hole (sound hole), (1102) is a front plate, and (1103) is a side plate.

 In particular, it is important to apply the compounding material (1) of the present invention to acoustic vibration members such as the above-mentioned front plate (1102) and sound plate (1103) as shown in FIG. Reference numeral (1103) denotes a side plate.

 [0061] In general, the musical instrument coated with natural ore such as graphite silica that emits far-infrared rays and negative ions according to the present invention is itself or in the sound range played by the instrument and emits far-infrared rays and negative ions. This will soften the heart of the listener who listens to powerful performances at or near the player, and at the same time gives the human body the physiological action of far-infrared rays and negative ions more effectively. And preventive effects can be enhanced.

 Explanation of symbols

 [0062] 1. Compounding material

 101, hitch pin

 102, bus bridge

 103, soundboard

 104, Long Bridge

 105, single string

 106, double string

 107, 3 strings

 108, Damba

 109, Les Pin

110, housing 201, Chu Jung Pin

202, frame

 203, bridge

 204, 3 strings

 205, double string

 206, single string

 207, Soft Petanole

208, sustaining petals

209, bass string

 210, bridge

 211, soundboard

 212, housing

 301, prop

 302, pedestal

 303, neck

 304, tuning nails

 305, disk

 306, string

 307, soundboard

 308, pedal

 309 legs

 401, swirl

 402, Itokura

 403, thread

 404, fingerboard

 405, string

 406, soundboard

407, piece 408, reverberation

409, E-line adjuster

410, clasp

411, destined for chin

 412, bow tip

 413, bow

 414 hair

 415, hair clip

416, side plate

 501, Machine head

502, thread

 503, nuts

 504, fingerboard

 505, frets

506, sound hole

 507, soundboard

 508, strings

 509, piece

 510, side plate

 601

 602, keyboard

 603, treble register

604, bass register

605, bus button

701, wooden bar

702, resonance tube

801, cylindrical

802, conical 803, barrel type

 804, hourglass type

 805, goblet type

806, drum with feet

807, long drum

808, frame drum

 809, leather

 810, torso

 901, soprano saxophone

902, tenor saxophone

903, Funore

 904, outlet

 905, head tube

 906, main

 907, foot tube

 1001, sound hole

 1002, front plate

 1003, side plate

 1101, Sound hole

 1102, front plate

 1103, side plate

Claims

The scope of the claims

 [I] A musical instrument characterized in that fine particles of graphite silica (black silica) that emit far-infrared rays and negative ions are blended into a paint and applied to a predetermined part of the instrument body and then Z or evaporated.

 [2] The fine particles of graphite silica (black silica) are 4 to 6% carbon by weight, magnesium 0.

 35 ~ 0.55%, silica 70 ~ 90%, titanium 1.0 ~ 2.0%, diacid ferrous iron 0.4 ~ 0.6%, Na 卜!; Kum 0.06 ~ 0.1% In the above-mentioned claim 1, the compositional power of 5-8%, anoleminicum, 0.8-2.0% potassium, 0.01-0.03% canoresicum, and 0.25-0.4% moisture Listed instrument

 [3] The graphite silica (black silica) fine particles have a far-infrared emissivity of 90 to 99 at room temperature.

The musical instrument according to claim 1 or 2, characterized by being emitted in a wavelength band of 2 to 18 microns called growth light and health light.

[4] The instrument according to any one of claims 1 to 3, wherein the graphite silica fine particles have a size of 10 microns or less.

[5] The musical instrument according to any one of claims 1 to 4, wherein the musical instrument is used while being held in the body.

 [6] The musical instrument according to any one of claims 1 to 5, wherein the musical instrument is used in close contact with a body.

 [7] The musical instrument according to any one of claims 1 to 6, wherein the musical instrument is a ukulele or a mandolin.

 [8] A musical instrument characterized in that fine particles of natural ore that emits far-infrared rays and negative ions are blended in paint and applied and Z or vapor-deposited on a specified part of the instrument body

[9] The natural ore fine particles have a far-infrared emissivity of 90 to 99% at room temperature, and are emitted in a wavelength range of 2 to 18 microns called growth light rays and health rays. The musical instrument according to claim 8

[10] The musical instrument according to [8] or [9], wherein the natural ore has a size of 10 microns or less.

[II] Any one of the above-mentioned claims 8 to 10, characterized by being used by being held in the body. Musical instruments described in

 [12] The musical instrument according to any one of claims 8 to 11, wherein the musical instrument is used in close contact with a body.

 [13] The musical instrument according to any one of claims 8 to 12, wherein the musical instrument is a ukulele or a mandolin.