RU2794060C1 - Method for manufacturing a musical instrument and a musical instrument made by the specified method - Google Patents

Abstract

FIELD: musical instruments.

SUBSTANCE: invention is intended to improve the sound quality of acoustic, electro-acoustic guitars and electric guitars made of wood. The technical effect, which consists in determining the place of installation and fastening of the resonator plates in accordance with the maximum increase in the resonant frequencies of the volume of air in the case, the increase in the frequency spectrum and the maximum duration of the sound of a musical instrument, is achieved due to the fact that in the method of manufacturing a musical instrument containing a case with an installed a string holder, a fingerboard with a peg mechanism fixed on the body, strings fixed on the string holder and a peg mechanism, and resonator plates installed in the case on the bases, according to the claimed invention, at least three resonator plates are fixed inside the case on the upper deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the volume of air in the case, while the place of attachment of the resonator plates is selected by using a microphone and a program for creating music, processing and mixing sound by determining the maximum increase in resonant frequencies of the volume of air in the case.

EFFECT: improving the sound quality of acoustic, electro-acoustic guitars and electric guitars made of wood

5 cl, 9 dwg

Description

The present invention relates to musical instruments and is intended to improve the sound quality of acoustic, electro-acoustic and electric guitars made of wood. The method provides improved sound quality, obtaining a sound of a higher volume level, with a bright thermal color, a dense focused sound and any given sustain.

Both the acoustic guitar and the electric guitar have many drawbacks: insufficient volume, lack of a good balanced sound, especially for low-priced guitars. For example, the top deck of acoustic guitars is usually made of plywood, while the deck of an electric guitar is made of low-quality wood. Guitars with fine wood tops sound good, but they are also expensive. There is a great need for a guitar capable of producing quality sound regardless of the material it is made from. The present invention provides an inexpensive, easily technologically implemented method that provides a significant improvement in audio performance.

There is known a way to improve the sound quality and volume of a conventional guitar, allowing you to control the sound characteristics. According to this method, a resonator plate having four arms and a cross-shaped center section can be placed cantilevered near the edge of a guitar body hole that defines a conventional guitar's sound hole using a detector clip. In this case, the other three sides of the resonant plate in the form of a cross are not fixed. The resonator plate installed in this way partially covers the sound hole and is located under many guitar strings. The detector clip (also referred to as the "detector") contains an upper prong that is located above the top surface of the top of the guitar and below the guitar strings, and two lower prongs that are located below the bottom surface of the guitar. Accordingly, the top and bottom prongs act as anchors, using the edge of the guitar's soundhole as a wedge held between them. The four arms of the resonator plate act as cantilever thin brass structures that effectively reverberate and transfer surface acoustic waves into the air, detected by the pointed ends of the top and bottom lugs, and are directed to the guitar's resonator plate. [US 6861581 B2, G10D 3/02 publ. 03/01/2005]

A device for improving sound is known, adapted for use with a banjo, containing a head and a support element for them, which, when assembled with each other, form a sound chamber of a generally cylindrical shape, and the support element includes a cylindrical rim with an inner surface, which, according to essentially as wide as a deep sound chamber, which includes a plate cut out of cardboard, the plate defining the main shaft and the first and second branches, each of the branches branching from each other at the junction of the branches with the main shaft in this way to form an open stem, the plate additionally having four partially circular inner edges, and three branches lined up along a significant part of the periphery of the open passage, each pair is separated from each other by one of the branches, with each of the branches protruding from the recessed edges of such an adjacent pair into the passage, oriented perpendicular to at least one of the other two branches; means comprising an elongated strip of double-sided adhesive tape, parts of which are attached to the main rod and, during operation of the device, to the cylindrical rim of the banjo, for hanging the plate from the parts of the inner surface of the rim, which are located at the top when the banjo is held in its playing position.

There is a known method of amplifying the sound of a banjo having a head and a support element for it, which, when assembled with each other, form a sound chamber of a generally cylindrical shape, while the support element includes a cylindrical rim with an inner surface that has the same width. , as is the deep sound chamber. The method includes the following steps: (a) bending a solid plate cut from a thick sheet of paper into a three-dimensional array, wherein the unbent portion of the plate defines the main stem and the first and second branches by the first and second corner end branches, respectively, wherein each of of the branches branches from the other at the junction of the branches with the main stem to form an asymmetric array with an open passage, the outlet of which is limited on one side by one of the side edges of the second angled end end on the side, while the side edge of the first angled end end is in close proximity deviates from said hole;

(b) wherein the three-dimensional array defines first, second and third flat surfaces, each of which intersects at least one of the other two flat surfaces, wherein the third flat surface is between the first and second flat surfaces, both of which pass, generally in the same direction from the third flat surface;

(c) while the first flat surface, which includes most of the first angular end end, intersects the side edge of the first angular end end in the immediate vicinity of said hole, with the first flat surface bending with the third flat surface; said bend extends perpendicular to the last side edge, keeping the open-ended passage generally free from contact with the periphery;

(d) wherein the second flat surface, which includes the majority of the second angular end end, including said side edge, which defines the entrance of the open end of the passage, is located generally perpendicular to the third flat surface, while the first flat surface is inclined from the second flat surface, and the first and second flat surfaces diverge from each other as they pass, each along its respective bend with the third flat surface, in the direction of connection of the branches with the main rod;

(e) suspending the three-dimensional array from portions of the inner surface of the rim which are generally at the top when the banjo is held in its playing position, the array being thus suspended from an elongated strip of adhesive tape the portions of which are variously attached to the main shaft and , during array operation, to the cylindrical rim of the banjo.

[US 20180247617 A1, G10D 1/10 publ. 08/30/2018]

The design of the above analogs does not allow full use of the property of the tool itself, in particular the body, its internal volume, shape, properties of the material from which it is made and, as a result, a low efficiency is obtained. The manufacture of a resonator plate from brass does not fully increase the duration of the sound of a musical instrument as a whole. The resonator plate in the design of musical instruments is made removable, which excludes the correct adjustment of the resonant frequencies of the volume of air in the case, the possibility of increasing the frequency spectrum (overtone) and the maximum duration of the sound of a musical instrument. The use of one resonator in a musical instrument does not provide amplification in the entire spectrum of amplitude-frequency characteristics (AFC).

A violin device is known, containing a soundboard, which is part of the body of such an instrument, a bass rod attached to the inner surface of the soundboard, a bridge, on which the strings are stretched from the shank. The loose soundboard rests on the main soundboard by means of two supports, the supports containing a kind of pin or short post attached in any suitable way to the bottom surface of the resonator. The pin is connected to the top surface or part of the auxiliary resonator. Free decks and their connections can be made from any suitable material. These connections can be made with glue, metal fasteners, or using a tenon protruding into the corresponding slots in several parts. Two of these supports are sufficient to keep the deck at a distance from the main deck. The supports are shaped to match the convexity of the soundboard and are parallel to it. [US 1351709 A, G10D 3/02 publ. 08/31/1920]

Known electric guitar containing connected to the body neck, string holder, peg mechanism, strings, pickup, resonators in the form of metal plates with a thickness of 1-3 mm and wooden plates with a thickness of 3-8 mm, which are installed in resonant chambers formed by the body wall and partitions, with In this case, grooves are made in the partitions. Metal and wooden plates are made rectangular. The metal plates are U-shaped, and the end fixed in the groove of the baffle is longer than the free end, which does not touch the body. [RU 155315, G10D 1/08, publ. 09/27/2015]

An electric guitar is known, comprising a neck connected to the body, a string holder, a peg mechanism, strings, a pickup and resonators in the form of metal plates, while the horseshoe-shaped resonators are placed in cylindrical holes made in the body, and at one of the free ends of the resonators wooden bushings for attaching to the body. Several resonators can be installed in one cylindrical hole. Wooden bushings are fixed to the rear wall of the cylindrical hole. Wooden bushings are fixed at the entrance to the cylindrical hole so that the resonators can have different lengths. [RU2655228, G10D 1/08, publ. May 24, 2018]

A wideband mechanical amplifier of the frequency characteristics of the sound of stringed plucked and bowed musical instruments is known, consisting of a base that is installed in an internal cavity on the surface of a musical instrument at an angle, and a plate, one end of which is fixed to the base, and the other end does not touch the body of the instrument. The free end of the plate can be made straight, can be bent at any angle, can be made with a bend of any radius, depending on the dimensions of the body of the musical instrument. [RU 2676504, G10D 3/00, publ. 12/29/2018]

However, the number of resonator plates installed in the musical instrument in the above known solutions does not allow to achieve the maximum increase in the frequency spectrum (overtone) and the duration of the sound of the musical instrument. Resonator plates in analogues are made of materials whose acoustic and resonant properties are defective, which does not allow achieving maximum sound duration. Mounting resonator plates on acoustic and electro-acoustic guitars on the back shell and in the area around the bridge and support bar is not effective for maximum results.

The technical problem of the claimed invention is the creation of a method for manufacturing a musical instrument with an increased frequency spectrum (overtone) and a maximum duration of sound (until the string vibration is completely attenuated) and the manufacture of a musical instrument in this way.

The technical results of the claimed invention are the determination of the place of installation and fastening of the resonator plates in accordance with the maximum increase in the resonant frequencies of the volume of air in the case, the increase in the frequency spectrum (overtone) and the maximum duration of the sound of a musical instrument. These technical results are achieved by the fact that in a method for manufacturing a musical instrument containing a body with an installed string holder, a neck with a peg mechanism mounted on the body, strings fixed on the string holder and a peg mechanism, and resonator plates installed in the body on the bases, according to the claimed invention, the plates at least three resonators are fixed inside the case on the top deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the volume of air in the case, while the place of attachment of the resonator plates is selected by using a microphone and a program for creating music, processing and mixing sound by determining the maximum increase in resonant frequencies of the volume of air in the case.

In a musical instrument made by this method, containing a body with a mounted string holder, a neck with a peg mechanism mounted on the body, strings fixed on the string holder and a peg mechanism, and resonator plates installed in the case on the bases, according to the claimed invention, resonator plates in the amount of at least three installed inside the body on the top deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the air volume in the body.

In a musical instrument made by this method, the resonator plate can be made of titanium and has a bend made in the form of a radius curve with the formation of larger and smaller parts; part of the plate, a longitudinal section is made with the formation of two strips, not equal in length, while the longer one is installed in the base. In a musical instrument made by this method, the resonator plate can be made of titanium and has a bend made in the form of a radius curve with the formation of larger and smaller parts; parts of the plate are made 2 longitudinal cuts with the formation of three strips, while two strips are of equal length, and the third longer one is installed in the base. In a musical instrument made by this method, the resonator plate can be made of titanium with a thickness of not more than 1.2 mm and has an inflection made in the form of a radius curve with the formation of larger and smaller parts, while the longer one is installed in the base.

To obtain an increase in the frequency spectrum and the maximum duration of the sound of a musical instrument, it is necessary to determine the exact location and fastening of the resonator plates in the body of the musical instrument. This is ensured by using a microphone and a program for creating music, processing and mixing sound, since the indicated device and software allow you to visually set the frequency spectrum (the number of vertical bands on the spectrogram) and the duration of the sound of a musical instrument (the length of the spectrogram band) from the spectrogram on a computer monitor. and thereby determine the exact location of the resonator plate to achieve maximum sound duration and increase the frequency spectrum.

When the string is excited (played), the soundboard of the acoustic guitar (electro-acoustic guitar) is excited. This excitation is transmitted to a group of resonator plates, which are fixed inside the case on the upper deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the air volume. The plates of the resonators begin to vibrate, transmitting additional vibrations to the top deck through positive feedback. The upper deck begins to vibrate more strongly, thereby amplifying acoustic and air waves, while the volume increases, the frequency range expands, the timbre takes on a juicy color, and the sustain increases.

The claimed method of manufacturing a musical instrument and a musical instrument manufactured by this method are illustrated by drawings, where figure 1 shows a general view of an acoustic guitar, figure 2 - a general view of an electric guitar, figure 3 - an option for installing resonator plates in an acoustic guitar, figure 4 - x-ray of an acoustic guitar with resonator plates installed, figure 5 - x-ray of an electric guitar with resonator plates installed, figure 6 - computer screen shot showing a spectrogram, figure 7 - resonator plate with one stripe, figure 8 - resonator plate with formation two bands, figure 9 - resonator plate with the formation of three bands.

A musical instrument made by the proposed method, contains a body 1 (Fig. 1, 2). A string holder 2, a neck 3 with a peg mechanism 4, strings 5 mounted on a string holder 2 and a peg mechanism 4 are installed on the body. 1. Resonator plates 7 can be installed in an amount of at least three inside the body 1 on the top deck 8 in the area of the string holder 2 located outside (Fig. 3, 4, 5) and neck attachment 3. The resonator plate 6 can be made of titanium and have inflection 9 made in the form of a radius curve (figure 7, 8, 9) with the formation of larger 10 and smaller parts 11. At the place of inflection 9 (fig. 8, 9) a cross section 12 is made, not exceeding 2/3 of the width of the resonator plate 7. In the greater part 10 of the resonator plate 7, a longitudinal section 13 is made with the formation of two strips 14, 15, not equal in length. The longer one 14 is installed in the base 6. On the base 6 (Fig. 5), two or more resonator plates 7 can be installed simultaneously, which, when installed in the base 6, can be oriented relative to the top deck 8 at an angle, parallel to the top deck 8 or perpendicular to the top deck 8.

The method is carried out as follows.

To determine the location of the resonator plates and, in fact, their installation to maximize the resonant frequencies of the air volume, an experimental sample of an acoustic guitar was prepared (Fig. 1, 4) Previously, 3 resonator plates were prepared, made of titanium and made in the form of a radius curve with an inflection 9 (Fig. 8) and the formation of more than 10 and less than 11 parts, on the first of them, at the place of the inflection, a transverse cut 12 is made, not exceeding 2/3 of the width of the resonator plate, while in the greater part 10 of the resonator plate, a longitudinal cut 13 is made, with the formation two strips 14 and 15, not equal in length, while the longer 14 is installed in the base 6. The second resonator plate also has a cross section 12 at the bend 9 (Fig. 9), not exceeding 2/3 of the width of the resonator plate, and in For the greater part of the resonator plate 10, 2 longitudinal cuts 13 are made with the formation of three strips, while two strips 15 are of equal length, and the third 14, which is longer, is installed in the base 6. The third resonator plate (Fig. 7) is made of titanium with a thickness of not more than 1.2 mm and also has an inflection 9 made in the form of a radius curve with the formation of a larger 10 and a smaller 11 parts, while the longer part 10 is installed in the base 6. Cross sections 12 in the first two resonator plates , made not exceeding 2/3 of the width of the resonator plate, since it is this configuration that makes it possible to obtain a greater sensitivity (fast response) of the resonator plate 7 for the maximum resonation effect. This configuration was obtained experimentally in the process of studying the effect of the upper soundboard on various resonator plates installed directly on the latter to obtain the maximum sensitivity of the resonator plates 7. Further, to install the resonator plates 7 (Fig. 3, 4 - x-ray), their base 6 is smeared from the mounting side adhesive composition (without final fixation) and temporarily installed in places inside the body 1 on the top deck 8 in the area located outside the string holder 2 (bridge) of the acoustic guitar through the acoustic hole 16 or, in the case of the removed back wall of the body 1 of the musical instrument, between the wooden spacers so so that the free end of the resonator plates 7 does not touch the free end of the guitar body 1. Then the microphone is connected and installed in a place with a maximum volume level (near the acoustic hole 16 on the top deck 8). For experimental tuning of the musical instrument, a CAD GLX 3000 microphone (another similar microphone can be used) and a Focusrite Forte sound card installed in the computer were used. The sound is produced with the thumb of the 3rd open G string in the middle of the acoustic hole 16 of the guitar with maximum amplitude. Measurements are made in the Logic pro x version 10.4.8. pre-installed on a computer, or in another similar program that provides the same functionality. To properly tune an acoustic guitar, sound levels (amplitude), frequency spectrum and sound duration (when the string is plucked) are measured without resonator plates 7 installed. The data are presented for an acoustic guitar on a spectrogram (computer screen shot) (Fig. 6). Upper spectrogram 17 (Fig. 6) without installed resonator plates 7, lower 18 (Fig. 6) spectrogram with installed resonator plates 7. Next, temporary installation of resonator plates 7 is performed without final fixation of the adhesive composition. After connecting the CAD GLX 3000 microphone and the Focusrite Forte sound card installed in the computer, the sound is produced with the thumb of the 3rd open G string in the middle of the acoustic hole 16 of the guitar with maximum amplitude and the necessary measurements are taken. To obtain the maximum results of the sound levels (amplitude), frequency spectrum and duration of the sound of the guitar, it is necessary to determine the exact installation location of the final mount inside the body on the top deck in the area of the resonator plates 7 located outside. To do this, each resonator plate 7 is moved separately, preventing touching the free part of the resonator plate of the body of the instrument, within the limits of the possible space allocated by the guitar manufacturer, while simultaneously observing the computer monitor, find the maximum amplification of sound levels (amplitude) on the spectrogram - the bandwidth of the visible frequency spectrum and the sound duration - the length of the visible frequency spectrum. Upon receipt of the maximum values, this position of the resonator plate 7 is fixed by the final fastening of the base 6 of the resonator plate 7. Next, the adjustment is made for the remaining resonator plates 7 in the same way. The measurement data in the program allow us to conclude that when recording the sound spectrum with one sound level, the spectrogram was enriched with additional frequencies. The spectrogram shows an increase in sound frequencies that were not previously detected during measurements, which clearly indicates the expansion of the frequency range and the manifestation of a sound signal at frequencies that were not previously visible on the spectrogram and not perceived by ear. In addition, the duration of the sound has changed from 8.250 to 10.750 seconds, respectively, the duration has increased by approximately 2.500 seconds.

Similar processes take place in electric guitars, and resonator plates, installed in places with a maximum increase in the resonant frequencies of the volume, literally make the body of the electric guitar vibrate, transmitting enriched and amplified vibrations to the pickup. The sound becomes rich, dense with good timbre coloring and sustain.

In the case of using resonator plates and installing them on an electric guitar (Fig. 2, 5), in the body 1 of the guitar inside the body 1 on the top deck 8 in the area of the string holder 2 located outside and the neck 3 is attached in places with a maximum increase in the resonant frequencies of the air volume, the plates resonators 7 are installed and adjusted to obtain the maximum effect of increasing the resonant frequencies of the air volume as follows.

To install the resonator plates 7 in the body 1 of the electric guitar, cavities are milled in the rear plane of the body 1, while the depth of the cavities and their configuration is selected in accordance with the geometric dimensions of the resonator plates 7 installed on the base 6. In this case, the depth of the cavities does not exceed the thickness of the body 1 of the electric guitar with the formation of a place inside the body of the electric guitar, excluding the physical contact of the free parts of the plates of the resonators 7 inside the cavity of the body 1 of the electric guitar.

12 (twelve) resonator plates were preliminarily prepared (Fig. 2, 5 - X-ray), made of titanium grade (OT-4.0).

Six resonator plates 7 are installed two by two on one base 6 - x-ray (Fig. 5) and are located on the base symmetrically to each other. In this case, the base 6 is installed so that the plates of the resonators 7, mounted on the base 6, are perpendicular to the top deck 8.

Resonator plates 7 (Fig. 8) are made in the form of a radius curve with an inflection 9 and the formation of larger 10 and smaller parts 11, on the first 10 of them, at the inflection point 9, a cross section 12 is made, not exceeding 2/3 of the width of the resonator plate, with in this case, in the greater part 10 of the resonator plate 7, a longitudinal section 13 is made with the formation of two strips 14 and 15, not equal in length, while the longer one 14 is installed in the base.

The seventh and eighth resonator plates 7 are fixed on the base 6 and are located parallel to the rear plane of the body 1. The ninth resonator plate 7 (Fig. 7) is fixed on the base 6 and is located relative to the strings 5 on the other side of the string holder 2, while the resonator plate 7 is oriented perpendicular to upper deck 8. The seventh, eighth and ninth plates of the resonators (Fig. 5) are made of titanium with a thickness of not more than 1.2 mm and also have an inflection 9 made in the form of a radius curve with the formation of a larger 10 and a smaller part 11, while the longer 10 part is installed in the base 6. The tenth, eleventh and twelfth plates of the resonators 7 (Fig. 5) are fixed on the base 6 and installed in the area of the base of the neck 3 of the electric guitar through the cavities in the rear plane of the body 1, previously prepared so that the free end of the resonator plates 7 did not touch the body of 1 guitar. The tenth plate of the resonator 7 is fixed on the base 6 and is oriented perpendicular to the top deck 8. The eleventh and twelfth plates of the resonator 7 are fixed on the base 6 and are oriented parallel to the top deck 8. The tenth, eleventh and twelfth plates of the resonators 7 (Fig. 7) are made of titanium not more than 1.2 mm thick and also have an inflection 9 made in the form of a radius curve with the formation of a larger 10 and a smaller part 11, while the longer part 10 is installed in the base 6. The transverse cuts 12 in the plates of the resonators 7 are made not exceeding 2/ 3 of the resonator plate width, since it is this configuration that allows the resonator plate 7 to be more sensitive (quick response) to maximize the resonant effect. This configuration was obtained experimentally in the process of studying the effect of the top soundboard on various resonator plates 7 installed directly on the last one, with the maximum sensitivity of the resonator plates 7 obtained. (rear plane of the fretboard 3) of the electric guitar through the cavities prepared earlier so that the free end of the resonator plates does not touch the body 1 of the electric guitar.

The optimal arrangement of the resonator plates is shown in the x-ray (figure 5). After that, connect and install the microphone in a place with a maximum volume level. For the experimental tuning of a musical instrument (electric guitar), a CAD GLX 3000 microphone and a Focusrite Forte sound card installed in the computer were used. The sound is produced with the thumb of the 3rd open string G with maximum amplitude. Measurements are made by the program Logic pro x version 10.4.8. pre-installed on a computer, or in another similar program that provides the same functionality. Measurements were taken on a Mexican-made fender stratocaster, with a bridge pickup on the third string. The break was made with the thumb with maximum effort in the area between the neck and middle sensors. The upper spectrogram (figure 5) shows the result before installing the resonator plates, the lower spectrogram after installing the resonator plates. The recording was made in line without changing the levels. The top deck 8 of the electric guitar begins to vibrate more strongly, thereby amplifying the acoustic and air waves, while the volume increases (bandwidth on the spectrogram), the frequency range expands, the timbre takes on a rich color, and the sustain increases. The measurement data in the program allow us to conclude that when recording the spectrum with one sound level (visible in the program interface), the spectrogram was enriched with additional frequencies (vertical stripes in the spectrogram), which clearly indicates the expansion of the frequency range and the manifestation of the sound signal at frequencies that were not previously visible on spectrogram and not perceived by the ear. In addition, the duration of the sound has changed from 8.250 seconds to 10.750 seconds, respectively, the duration has increased by approximately 2.500 seconds.

Installing resonator plates in the body of an electric guitar allows not only to increase the performance of high, medium and low frequencies of the instrument, but also to add additional color to the sound at the initial stage of extraction by obtaining new overtones, and also to increase the signal by amplifying resonant frequencies. The sound is tight, well focused and has very good sustain. The difference is even audible. The duration of the sound when listening to experts in this field increases by more than 10 seconds.

Claims (5)

1. A method for manufacturing a musical instrument containing a body with a mounted string holder, a neck with a peg mechanism mounted on the body, strings fixed on the string holder and a peg mechanism, and resonator plates installed in the case on bases, which consists in the fact that the number of resonator plates is not less than three are fixed inside the body on the top deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the volume of air in the body, while the place of attachment of the resonator plates is selected by using a microphone and a program for creating music, processing and mixing sound by determining the maximum increase in resonant frequencies of the volume of air in the case. 2. A musical instrument manufactured by the method according to claim 1, containing a body with a mounted string holder, a neck with a peg mechanism mounted on the body, strings fixed on the string holder and a peg mechanism, and resonator plates mounted in the body on bases, characterized in that the plates at least three resonators are installed inside the body on the top deck in the area of the string holder located outside in places with a maximum increase in the resonant frequencies of the air volume in the body. 3. A musical instrument of claim 2, characterized in that the resonator plate is made of titanium and has an inflection made in the form of a radius curve with the formation of larger and smaller parts, while a cross section is made at the inflection point, not exceeding 2/3 of the plate width, and in the greater part of the plate, a longitudinal section is made with the formation of two strips, not equal in length, while the longer one is installed in the base. 4. A musical instrument of claim 2, characterized in that the resonator plate is made of titanium and has an inflection made in the form of a radius curve with the formation of larger and smaller parts, while a cross section is made at the inflection point, not exceeding 2/3 of the plate width, and in most of the plate, 2 longitudinal cuts are made to form three strips, while two strips are of equal length, and the third, longer one, is installed in the base. 5. A musical instrument of claim 2, characterized in that the resonator plate is made of titanium with a thickness of not more than 1.2 mm and has an inflection made in the form of a radius curve with the formation of larger and smaller parts, while the longer one is installed in the base.

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