EA044853B1 - BOW INSTRUMENT - Google Patents

Description

Field of technology to which the invention relates

The subject of the invention is a bowed instrument containing a body and a neck, the upper surface of the body being the upper soundboard, in the lower part of which there is a tailpiece attached to the bottom of the instrument, while the strings are in a tense state, being supported from below by a stand between the tailpiece and the neck scroll.

State of the art

There are several traditional bowed instruments. In the violin family, the tailpiece is a piece carved from ebony or rosewood that is connected to a button attached to the lower lock by the tension of the string. On the mandolin and some metal-string acoustic and electric guitars, it is made of metal and screwed to the bottom cleat or body of the instrument. In guitars, the tailpiece and bridge are often made in one piece (as one piece), for example in the case of classical and flamenco guitars. In plector instruments of antiquity and in folk instruments (rosette type), the string stand also forms a tailpiece.

Strings are the main sound-generating components of bowed instruments.

A string is a thin flexible strand that, when stretched, is capable of transverse vibrations. It is usually made from animal guts, silk, plastic or metal (the original meaning of the Hungarian word hur for string was gut). The sound character of bowed instruments is mainly determined by the strings, but it also depends on the design of the instruments, since the sound created by the strings is emitted by the body of the instrument.

String vibration can be caused in a variety of ways, including:

plucking (either manually with your fingers, or using a hand plectrum or mechanism, such as a harpsichord), striking (using a mechanism, such as a piano, or manually with a mallet, such as a dulcimer), friction (using a bow, such as in bowed instruments, or a mechanism, for example, like a barrel organ), in some cases the vibration of the strings is caused by an air flow (Aeolian harp).

On a string emitting sound with a constant pitch, standing waves arise: the cycle time of vibration of the string is determined by its free length. The magnitude or amplitude of the vibration determines the loudness, while the frequency of the vibration determines the pitch of the sound generated. Other characteristics of the string, such as its material, thickness, etc., as well as the player's touch on the string, affect the timbre of the tone. Adjusting the pitch of the sound produced by a string (tuning) is done for most instruments by changing the amount of tension on the string.

If a stretched string, fixed at both ends, deviates from its original state at a given point, then it takes on an elongated triangular shape, and after it is released, the angle of the triangle begins to move in both directions along the string, moving back and forth and changing direction at the end points while the string tries to return to its original state. It is important to note that the motion characteristics of the string are highly dependent on the location of the excitation, but this does not affect the frequency of the sound. When plucking, the vibration is damped due to internal friction, but when using the bow, the state characteristic of the moment of plucking can be maintained continuously.

In order for the string to be suitable for musical purposes, i.e. In order for it to produce musical sound for as long as possible, it must satisfy the following conditions:

it must have sufficient tensile strength to withstand the tensile forces required for tuning, it must be flexible enough to actually behave like a string rather than a vibrating flexible rod, therefore it is important that the material if it is harder or more rigid (for example, steel), had a fairly large length-to-diameter ratio, but, for example, a silk thread wrapped in a bronze strand will work with a relatively smaller length-to-diameter ratio, its longitudinal mass distribution should be uniform. This does not exclude the combination of materials of different densities.

Presumably, the first bowed instruments were the so-called idiochord instruments. They were made from the stems of various plants by making longitudinal slits in the stem and stretching the fibrous bundle thus separated with small wedges at the ends. For example, a cornstake fiddle has this configuration.

The next stage of improvement was the heterochord musical bow. This instrument uses a string made from twisted animal or plant fibers to meet more stringent musical requirements.

When improving bowed instruments in different regions of the globe, different materials were used to make musical strings: in the East - silk, in Asian nomadic cultures with horse breeding - horse hair, in tropical regions - various plant fibers, and in the West they were mainly used for this purpose animal intestines (catgut).

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High quality catgut strings are made from the intestines of sheep, goats or lambs, but for more modest purposes the intestines of calves, rabbits or cats are also suitable. The intestines are mainly composed of muscle fibers, which explains their extreme elasticity. After cleaning, bleaching, etc. the guts are cut into thin strands, after which as many strands are twisted together as required to produce a string of the required diameter, which is then dried, ground and polished.

For thousands of years, gut strings were the most common type of string, but in the mid-20th century they began to be replaced by plastic. The sound quality of nylon strings is equal to that of gut strings, and nylon strings are more durable.

Metal strings also have a long history: in the past, the main materials for their production were copper and bronze. Steel strings began to become widespread in the 19th century, first used for the piano and then for the violin. During the 20th century, aluminum also became a material for making strings.

The violin is the smallest and highly tuned member of the violin bow family, having 4 strings tuned a perfect fifth apart. The family also includes the viola, cello (or cello) and double bass.

The lowest-pitched string is tuned as the G of the small octave, that is, G ₃ , followed by the D strings of the first octave (D4), A of the first octave (A ₄ ) and E of the second octave (E ₅ ).

Music for the violin is usually written in the treble clef (or, in other words, in the clef of G).

Due to the increasingly stringent demands placed on the instrument, it became one of the instruments that required the most sophisticated experience in the manufacture of musical instruments. The combination of careful assembly and the development of highly complex instrumental technique has resulted in a high-performance instrument, providing virtuosity, dynamic and timbral range that is superior to other bowed instruments. The violin is probably the most popular - and certainly the most common and most sought after - of all bowed instruments.

The modern form of the violin emerged around the 15th century. Its main components are the shell (sides), the arched top, the front and back, the neck ending in a scroll, the neck, the tailpiece, the bridge and the pegs. The design, shape and size of the violin, based on the golden ratio, proved so perfect that this configuration is still used today.

The shape, configuration and structural components of the violin have remained virtually unchanged over the past 300 years, and the composition of the adhesives used to assemble the components and the composition of the dyes and varnishes used to treat the surface of the materials also remain the same.

The configuration of conventional violins is described with reference to FIGS. 1. Violins contain a body 2, which forms the resonator body of the instrument. Its function is to transmit the vibration of the strings and emit it in the form of sound into the surrounding space. When viewed from the front, it has a distinctive hourglass shape, and its tapered waist allows the bow to move freely to strike either string.

The top panel of the body 2 is a top deck 4, which preferably consists of two pieces of radially sawn spruce, symmetrically joined together in the middle and cut to a slightly arcuate shape. This is the component whose material, shape, thickness and coating have the greatest impact on the sound quality of the instrument. The bridge 13, a particularly complex component designed to transmit the vibration of the strings 14 to the top soundboard, is adjacent to the latter near the middle. The so-called f-holes 10, which, on the one hand, are used to facilitate the upper soundboard to ensure freer vibration of the stand 13, and on the other hand, are intended to provide a certain degree of openness of the cavity of the resonator body, that is, the body 2, are located symmetrically on both sides of the stand 13. The upper deck 4 is reinforced from the inside with a longitudinally extending rod - the so-called spring, which is located slightly asymmetrically under the strings of the lower tuning.

At the rear, the body 2 ends with a lower deck 6, which has a configuration similar to the upper deck 4, with the difference that it is made of a harder material, that is, maple wood, and contains neither a hole nor a spring. It can be made as a single unit or by connecting two symmetrical parts, just like the upper deck 4.

The upper deck 4 and the lower deck are connected to each other by shells 5; Due to the special shape of the violin, the sides consist of six separate plates of maple wood, which are bent into different shapes and fastened together using so-called clots. On the inside of both of their edges there are so-called hoops to increase the surface area of the clutch for attaching the top 4 and back 6. The hardwood button 24, which holds the tailpiece 9 (which optionally also includes machines for fine tuning) is connected with the bottom clot. This component is designed to secure the ends of the strings facing the performer.

Violin sound spacer (also called darling, that is, soul - ame, in continental

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Europe) is a small cylindrical rod located inside the instrument and sandwiched between the upper soundboard 4 and the lower soundboard 6, approximately under the side of the stand 13, which is located under the high action strings. It is not secured by gluing, so its position can be adjusted using a special tool inserted into ef 10.

If you remove it, the instrument will become completely silent, but moving it even by a millimeter leads to significant changes in sound quality. This component can be found in most bowed instruments, its main function is to convert bow-induced vibrations of the strings 14 (which are almost parallel to the plane of the top 4) into vibrations in a plane perpendicular to the top 4 so that they can be transmitted to the top 4. This is achieved thanks to the cushion providing a relatively strong support (pivot point) under one of the legs of the stand 13, so that almost all of the vibrational energy can be transferred to the other leg, and this energy can then be distributed throughout the upper deck 4 by means of a spring.

The neck 1 is attached to the upper part of the body 2, slightly inclined relative to the longitudinal axis of the body. It is made of maple wood, and on its upper side there is a fingerboard 3, which extends longitudinally over the top soundboard 4. At its other end there is a tuning box 7 with a curl-shaped head 8 and pegs 12. The performer produces notes of different heights by pressing the strings down to the fingerboard 3, therefore the shape of the neck 1 is such that it fits ergonomically in the palm of the performer. The neck 3 is made of ebony and has a slightly convex cross-section corresponding to the curvature of the stand 13. At the distal end of the neck 3 there is a nut 11, which forms one of the end points of vibration of the strings 14.

A head that ends with a thread in the shape of a curl can be considered the calling card of the instrument manufacturer. This is observed to such an extent that if the neck 1 of a valuable instrument is replaced, the head is cut off from the original neck 1 and installed as a replacement. From the nut 11, the strings pass to a groove-shaped recess in the tuning box 7, where they are wound onto transversely inserted tuning pegs 12. The latter are made from ebony or grenadilla wood by turning; It is important that they are very accurately installed - using a conical fit - in the head bores, because the precise adjustment of the tool depends on the quality of this installation. The conical shape is important for proper fixation of the pegs.

As for the materials used for the manufacture of instruments, the top soundboard, spring, earpiece, chokes and hoops are made of softwood, that is, spruce, and the bottom soundboard, sides, neck, peg box with curl and nut are made of semi-hard deciduous wood species, that is, from maple. Ebony is used to make the neck because it is subject to high stress and wear. The tuners, tailpiece, button and chinrest may be made from rosewood, boxwood, ebony or other rare woods.

The strings of the instrument are located between the tailpiece and the head.

The configuration of a conventional tailpiece 9 forming the lower attachment points of the strings 14 is shown in FIG. 2. The tailpiece 9 is initially a small solid metal plate with four holes 15 located along the upper, wider end, and with small narrow slots - not shown in the drawing - connecting to the holes. The holes 15 and slots - GDAE - designed to receive the strings 14 are made relatively narrow to facilitate installation and handling of the strings 14. The nut of a conventional tailpiece 9 has an edge machined to a hemispherical shape. It is important that all parts of the tailpiece are rounded.

Over the centuries, tailpieces have been modified several times. Such a modification was developed, for example, by Zalm, who tried to secure the upper end of the tailpiece, and replaced the slots with holes, securing the strings passed through them using knots.

His intention was to increase the resistance of the strings and to achieve regular vibration of the strings.

To attach the tailpiece 9 to the button, pieces of thick string were usually used (see O.R. Apain Bennewiti: A hegedu epites alapismeretei (Fundamentals of Violin Construction), Ernh Friedr Voight Kiado 1892, Hungarian translation reprinted in 1992 and privately published in 2004 G.).

A number of technical solutions have been proposed to further improve the string holders of bowed instruments. Such solutions are disclosed in documents DE 19515166 A1, EP0242221 A2, DE 29712635 U1, US 5883318, DE 2845241 A1, WO 2012/150616 and EP 0273499 A1.

The inventions EP 1260963 and HU 225320 disclose a tailpiece which essentially retains the shape of the tailpieces shown in FIG. 2. The tailpiece has a tailpiece body on which is located a string holding mechanism containing an engaging bracket forming an engagement arc for attaching the tailpiece to a musical instrument.

To facilitate operation, the body of the tailpiece contains an adjustment mechanism for adjusting the distance from the top of the arc of engagement of the engaged string from the tailpiece, and the adjustment mechanism can be operated from the direction of the side of the tailpiece.

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In the case of the tailpiece disclosed in US 2012/0285311, the holes for receiving the strings are arranged along an asymmetrical arcuate hole, resulting in the strings having different lengths.

The document US 2017/0278489 discloses a tailpiece, mainly for a plucked instrument, which is made in the form of a multi-layer hollow tailpiece in which holes for receiving strings are located along the arcuate side.

The string tension is adjusted using pegs.

US 2003/0217633 discloses a tailpiece for bowed instruments located on the top of the instrument and attached to the top on the lower oval of the instrument for receiving the lower portion of the strings. This famous tailpiece can be thought of as a shortened version of a regular tailpiece, lacking the extended portion of the stem of a regular tailpiece (the top of which contains the holes into which the instrument's string is inserted).

Known technical solutions, on the one hand, have a complex configuration, and on the other hand, they are essentially variants of a conventional tailpiece, but do not have a significant impact on the sound of the instrument.

The essence of the invention

The object of the present invention is to provide a bowed instrument comprising a tailpiece that eliminates the disadvantages of prior art solutions, provides easier operation and a significantly improved and more enjoyable sound.

The invention is based on the recognition that by providing an arcuate configuration of conventional elongated tailpiece string tops and attaching the strings to the top of the tailpiece at different heights, free movement of the resonator body and strings can be improved, resulting in a more responsive sound of the instrument. , since the resistance of the strings is significantly reduced, the resonance of the strings becomes controllable, and in addition to this, the vibration of the strings, which are stretched to different degrees, becomes more uniform, which greatly improves the sound of the instruments.

Another distinctive feature of the invention is that a bowed instrument containing a tailpiece according to the invention has strings of different lengths, and due to the configuration of the tailpiece, their stretching is more uniform, so the strings will be easier to extract sound from and their sound will be softer.

These objects according to the invention were achieved by providing a bowed instrument comprising a body and a neck, the upper surface of the body being a top soundboard, at the bottom of which is a tailpiece attached to the bottom of the instrument, the strings are in a tensioned state and are supported from below by a stand between the tailpiece and curl of the neck, while the bowed instrument contains a tailpiece designed to hold the lower part of the strings, which has an arched-triangular shape, has an asymmetrical body made of multilayer material, and is rounded around the perimeter of its body, with a hole intended for attaching the tailpiece to the bottom of the bow instrument, located in the lower corner, while the holes, having different lengths and designed to receive strings, are located along the arcuate part passing between its two upper corners.

In one preferred embodiment of a bowed instrument according to the invention, the tailpiece is a multi-layer body consisting of a main body, at least one reinforcing layer surrounding the main body on both sides, and a layer of at least a single layer of coating surrounding the reinforcing layer on both sides , and the main part is made of wood material of at least the following species: ebony, mahogany, afzelia, iroko, afrosia, cabreuva, lapacho, teak, rosewood, jatoba, merbau, mutenier, wenge, panga-panga, kempas, bangkirai, haya, wherein the reinforcing layer(s) are made of at least one of the following materials: Kevlar, carbon fabric, graphene.

In another preferred embodiment of the bowed instrument according to the invention, there is an adhesive bond between the layers of the multi-layer tailpiece body, the adhesive bond layers being made of a cyanide-containing adhesive and/or a thermosetting adhesive resin.

In yet another preferred embodiment of a bowed instrument according to the invention, the openings of the tailpiece for receiving strings are configured with rounded edges.

In one advantageous embodiment of a bowed instrument according to the invention, the function describing the arcuate portion extending between the corners of the arcuate portion of the upper portion of the tailpiece for receiving the lower end of the strings is a functional portion defined by the following equation and values:

y = a+bx+cx ² +dx ³ +ex ⁴ +fx ⁵ xe[-12.96...; 20.84...]

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Another advantageous embodiment of a bowed instrument according to the invention further comprises a spacer element or spacer elements located between the bridge and the tailpiece and designed to move up and down along the strings, the spacer elements having a bar-like configuration with formed on their sides recesses designed to receive strings.

The string lengths applicable to the bowed instrument of the invention are shown in the table below.

Brief description of drawings

The bowed instrument according to the invention and its tailpiece are explained in detail with reference to the accompanying drawings, where in FIG. 1 shows a front view (a) and a side view (b) of a bowed instrument - a violin - with a known tailpiece, in FIG. 2 is an enlarged view of the tailpiece shown in FIG. 1, in fig. 3 shows a side view of a bowed instrument, in particular a violin, according to the invention; FIG. 4 is a partial front view of the bowed instrument of FIG. 3, in fig. 5 shows an axonometric view of a tailpiece for a bowed instrument according to the invention; FIG. 6 is a front view of the tailpiece of FIG. 5, in fig. 7 shows a rear view of the tailpiece of FIG. 5, in fig. 8 shows a top view of the tailpiece of FIG. 5, in fig. 9 shows a bottom view of the tailpiece of FIG. 5, in fig. 10 is a view taken in the section plane I-I of FIG. 5, in fig. 11 shows a curve describing the upper part of the tailpiece of FIG. 5, in fig. 12 shows a spacer element used with a bow tool according to the invention, and FIG. 13 is a side view of the spacer element of FIG. 12.

Best Mode for Carrying Out the Invention

In fig. 3 shows a side view of a bowed instrument, in this case a violin, according to the invention.

The configuration of the bowed instrument according to the invention is substantially identical to that of the conventional instrument shown in FIG. 1, that is, the configuration of the body 2 and neck 3 has not changed.

The role of the stand 13 was taken over by the stand 25. However, the configuration of the tailpiece 16, located in the lower part of the instrument, is completely different from the known technical solutions. The configuration of the tailpiece 16 will be described in detail below.

The tailpiece 16 is designed to receive the lower end of the strings 14, with the tailpiece 16 attached to the bottom of the instrument at one point by a button 24.

In fig. 4 shows the bowed instrument of FIG. 3 is a front view also showing the strings, with spacers 26 configured to move up and down along the strings 14 and positioned between the tailpiece 16 and the bridge 25 to eliminate unwanted out-of-tuning sounds.

It should be noted that the spacers 26 are included optionally, that is, they may be absent.

In fig. 5 shows the configuration of the tailpiece 16 of a bowed instrument according to the present invention in perspective view.

The tailpiece 16 is a body with an upwardly flared configuration, in which the right upper end, formed symmetrically with respect to the axis 17, has a large length. The tailpiece 16 is essentially a body having an asymmetrical arcuate triangular shape, the angle c of which is higher than the angle a, while the angles b and c are connected to each other by an arcuate part 19 (see Fig. 6), said arcuate part 19 forms the upper blow side

- 5 044853 number holder 16.

Above the lower corner a of the tailpiece there is a hole 18 intended for attaching the tailpiece 16 to the bottom of a bowed instrument, for example a violin, that is, to its button 24 (see Fig. 3).

It should be noted here that in general a single hole is usually sufficient to attach the tailpiece 9 to the instrument, but in some cases a two-hole mounting may also be considered. Such fastenings can be realized using through or countersunk holes.

Single-point mounting has a more favorable effect on tool co-vibration. In the case of a two-point attachment, the above co-vibration can be reduced, causing the vibration of the lower portion of the string (located below the bridge 25) to become more dominant.

Along the arcuate part 19 connecting the upper corners b and c of the tailpiece 16, there are four holes 20 designed to receive strings (the latter are not shown in the drawing, see Fig. 6). The holes 20 have a beveled/rounded edge configuration.

Strings G and E are secured in a hole 20 at angle b and in a hole 20 at angle c, respectively, while strings D and A are secured along an arcuate portion 19 connecting angles b and c on either side of axis 17 .

In fig. 7 shows a rear view of a tailpiece 16 of a bowed instrument according to the invention. It should be noted that, if the characteristics of the instrument permit, the tailpiece 16 may be attached to the instrument in this configuration as well. In this case, the G and E strings will, of course, be secured in the hole 20 located at the uppermost angle c of the tailpiece 16, and in the corner b, respectively.

In fig. 8 and 9, the tailpiece 16 is shown in top and bottom views, respectively.

As shown in FIG. 5-9, there are no sharp edges and corners on the sides of the tailpiece 16, i.e. all edges have a rounded shape. It should be noted that the tailpiece 16 may have a convex or flat configuration.

In fig. 10 is a sectional view along the sectional plane I-I of FIG. 6.

The tailpiece 16 is a solid body consisting of many layers. Depending on the type of materials used and the characteristics of the tool, the number of layers varies from 7 to 14.

In this embodiment, the tailpiece 16 is a violin tailpiece, the tailpiece 16 being composed of the following layers: an inner body 21, a reinforcing layer 22, a cover layer 23, wherein the inner body 21 is made of ebony. The base 21 is surrounded on both sides by a corresponding reinforcing layer 22, preferably made of Kevlar, the layers 22 on each side are covered with two covering layers 23, which are made of ebony, mahogany, afzelia, iroko, afrosia, cabreva, lapacho, teak, rosewood, Jatoba, merbau, mutenie, wenge, panga-panga, kempasa, bangkiraya, haya.

Instead of Kevlar reinforcement, carbon fabric and graphene can also be used.

The layers may be bonded together using a cyanide-containing adhesive and/or a thermosetting adhesive resin.

In the case of an instrument including a tailpiece 16, the tailpiece 16 is attached to a button 24 on the bottom of the instrument at one point, causing the tailpiece 16 to be tilted relative to the strings 14.

For a violin, the axis of this tilt will be parallel to the strings, while for a double bass and viola the tilt angle is preferably 3.7°, and for a cello 7.8°.

This tilt has a beneficial effect on the sound of the instrument.

In fig. 11 shows a function curve - a polynomial function - which describes an arcuate part connecting points b and c of tailpiece 16.

y = a+bx+cx ² +dx ³ +ex ⁴ +fx ⁵ where y = 0.000000000000000888 + 0.0163847606654536x + 0.0326450466094223x ² + 0.000710668554553942x3 + 0.0 00083073284331152x ⁴ + -0.000001250897129314x ⁵ xb [- 12.96...; 20.84...]

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Ha Wa A 0.000000000000000888 R ² -12.96831103 9.6360373 b 0.0163847606654536 aR ² -9.4331008 4.09804496 With 0.0326450466094223 R 0 0 d -0.000710668554553942 S.E. 1.82034226 0.13460043 e 0.000083073284331152 F 13.57826781 6.70859988 f -0.000001250897129314 20.84428892 18.84923295

Second order polynomial: (SSE = 0.547) heh [0.53]

-0.00938455 x ² + 0.52331792 x - 0.01674261.

Third order polynomial: (SSE = 0.403) heh [0.53]

3.97677664 10 ^-5 x ³ - 1.25425892 10 ^-2 x ² + 5.84860760 10 ^-1 x - 1.73194702 10 ^-1 .

Fourth order polynomial: (SSE = 0.106) xe [0.53] y = (4.24340772 10 ^-6 ) x ⁴ - (4.07083511 10 ^-4 ) x ³ + (1.98383363 10 ^{- 3} ) x ² + (4.39330062 10 ^-1 ) x (3.13336927 10 ^-2 ).

Approximating measured points:

[x, y]=0; 0

8; 3.3

18; 6.8

28; 7.3

38; 6.13

48; 3.12

53; 1.7.

The part of the function that determines the values of the arcuate part 19 is obtained using the values calculated for the approximating points (x, y).

It should be noted that the function describing the arcuate portion 19 is also a family of parametric functions.

Now returning to the configuration of the tailpiece 16: as already noted, the tailpiece 16 does not have any sharp corners or edges, and all its edges are beveled/rounded; Moreover, in order to make its constituent layers invisible - like the bowed instrument itself (see Fig. 1), - its outer part is equipped with a coating, which can be made as a single whole or consist of many interconnected parts.

It was noted here that the default tailpiece may be installed without fine tuning machines, but if the characteristics of a given instrument require it, fine tuning machines may also be included.

To fine-tune and eliminate possible out-of-tuning sounds, the bowed instrument of the invention may also include a spacer (or spacers) 26 located between the strings 14 and offset/offset upward or downward between the tailpiece 16 and the bridge 24 (see FIG. 4).

The configuration of the spacer 26 can be seen in FIG. 12 and 13.

The spacer element 26 is essentially an elongated bar-shaped element with recesses made on its side surfaces for receiving strings 14.

As can be seen from the configuration of the tailpiece 16 for bowed instruments according to the invention, unlike instruments equipped with conventional tailpieces (see FIG. 1), the strings have different lengths. The length of the lower section of the string - the E string, fixed in the hole at the 20th angle c - is the shortest, but the lengths of certain strings differ from the length of the strings used for instruments with conventional tailpieces.

This makes a significant difference in sound and also makes the instrument easier to handle.

It should be noted that although the configuration of the instrument of the invention and the tailpiece used therefor have been disclosed in relation to a conventional violin, the tailpiece can be used on any other bowed instrument, with string lengths varying depending on the characteristics of the particular instrument.

The string tuning of bowed instruments is as follows (starting from thicker strings to thinner strings):

violin: GDAE, viola: CGDA, cello: CGDA, or, for a five-string baroque cello: CGDAE, double bass: EADG, or, for a five-string double bass: EADGB.

String lengths used for bowed instruments containing a tailpiece 16

- 7 044853 according to the present invention are summarized in the table below:

Tool String name Overall Length (mm) String B length of twisted section above the bottom button (mm): length of metal used for playing twisted section of the string (mm): length of the upper twisted section for winding on the peg Violin G 510-680 10-30 400-500 100-150 D 580-700 10-30 470-520 100-150 A 600-740 10-30 470-530 120-180 E 540-660 10-30 450-500 80-130 Alto WITH 645-795 15-35 530-600 100-160 G 685-820 15-30 540-620 130-170 D 735-835 15-35 570-620 150-180 A 675-795 15-35 530-590 130-170 Cello WITH 1140-1235 40-60 960-1010 140-165 G 1150-1240 40-60 970-1020 140-160 D 1190-1290 40-60 970-1020 180-210 A 1180-1260 40-60 950-980 190-220 Double bass E 1880-1950 50-70 1600-1630 230-250 A 2020-2095 50-70 1640-1665 330-360 D 2050-2115 50-70 1650-1675 350-370 G 2010-2725 50-70 1650-1675 310-340

The string holder for bowed instruments according to the invention has the following advantages:

acts as a means of controlling resonance, through its use it is possible to achieve a larger, more resonant sound and a wider range of sounds, although the decay time of the sound is not much longer compared to conventional tailpieces, through the use of appropriate bowing technique a richer and more dynamic sound can be achieved; it seems that there is an additional layer of resonance to shape the sound, making daily practice on the instrument more enjoyable, the resistance of the semitones that arise during playing the instrument is reduced and made more uniform, which allows for greater differences in volume, vibrations of the lower part of the string (located downwards) from the stand) contribute to the formation of a new frequency range; In addition, it makes the wolf tone (which can be found on almost all high-quality bowed instruments) controllable, reducing or completely eliminating its naturally incompatible vibrations, making the instrument subjectively much easier to play, which is primarily manifested in a more flexible application of pressure on the string with the left hand , and in the case of the right hand (with a bow) - in the vibration of the strings more easily achieved with the help of the bow, the vibrato (that is, the periodic change in pitch performed by the performer's left hand) also becomes more dynamic - the spectral range of the vibrating sound becomes wider demonstrating an unprecedented additional quality , which opens up completely new possibilities in creating sound, which can also lead to new directions of development in instrumental practice, while learning to play bowed instruments, makes tuning the instrument easier (more audible) for the student.

List of item numbers:

- neck,

- frame,

- vulture,

- upper deck,

- shell,

- lower deck,

- peg box,

- curl,

- tailpiece,

- ef,

- threshold,

-

Claims (11)

12 - pegs, 13 - stand, 14 - string, 15 - hole, 16 - tailpiece, 17 - axis, 18 - hole, 19 - arcuate part, 20 - hole, 21 - main part, 22 - strengthening layer, 23 - cover layer, 24 - button, 25 - stand, 26 - spacer element. CLAIM 1. A bowed instrument containing: a neck (1) with a scroll (8), a body (2), the upper surface of the body (2) representing the top soundboard (4), a tailpiece (16) attached to the bottom of the body and instrument, a bridge (25), and strings ( 14), which are in a tense state between the tailpiece (16) and the curl (8) of the neck (1), while the strings (14) are supported from below by a stand (25), characterized in that the tailpiece (16) is designed to hold the lower part strings (14) and has an upwardly flaring shape with a rounded perimeter, an asymmetrical solid triangular body with three corners (a, b, c), with one single hole (18) located in the lower corner (a), from which the said tailpiece body extends upward , and the tailpiece is attached to the bottom of the instrument through said single hole (18), wherein additional holes (20) are configured to receive the bottom of the strings (14) and are located along an arcuate portion (19) extending between the two upper corners (b , c), and also by the fact that the strings (14) have correspondingly different lengths. 2. A bowed instrument according to claim 1, characterized in that the tailpiece (16) is a multi-layer body formed by a main part (21), at least one reinforcing layer (22) surrounding the main part on both sides, and a layer (23 ) at least one layer of coating surrounding the reinforcing layer (22) on both sides. 3. A bowed instrument according to claim 1 or 2, characterized in that the main part (21) of its tailpiece (16) is made of wood material of at least one of the following species: ebony, mahogany, afzelia, iroko, afrosia, cabreuva , lapacho, teak, rosewood, jatoba, merbau, mutenier, wenge, panga-panga, kempas, bangkirai, haya. 4. A bowed instrument according to claim 1 or 2, characterized in that the material of at least one reinforcing layer of the tailpiece (16) is one of the following materials: Kevlar, carbon fabric, graphene. 5. A bow instrument according to any one of claims 1 to 4, characterized in that there is an adhesive connection between the layers (21, 22, 23) of the multi-layer tailpiece body (16). 6. A bowed instrument according to claim 5, characterized in that the adhesive connection between the adhesively bonded layers of the tailpiece (16) is formed by a cyanide-containing adhesive and/or a thermosetting adhesive resin. 7. A bowed instrument according to any one of claims 1 to 6, characterized in that the holes (20) of the tailpiece (16), intended for receiving strings, have a beveled/rounded edge configuration. 8. A bow instrument according to any one of claims 1 to 7, characterized in that the function describing the arcuate portion passing between the corners (b, c) of the arcuate portion (19) is a functional portion defined by the following equation: y = a+bx+cx ² +dx ³ +ex ⁴ +fx ⁵ , where the coefficients of the equation have the following values: - 9 044853 a 0.000000000000000888 b 0.0163847606654536 s 0.0326450466094223 d -0.000710668554553942 e 0.000083073284331152 f -0.000001250897129314 in which case the specified equation is a polynomial approximation on the interval [-12.96...; 20.84] x values at the following points: X U -12.96831103 9.6360373 -9.4331008 4.09804496 0 0 1.82034226 0.13460043 13.57826781 6.70859988 20.84428892 18.84923295 9. A bowed instrument according to claim 1, characterized in that it additionally contains a spacer element or spacer elements located between the bridge (25) and the tailpiece (16) and made/made to move up and down along the strings (14) . 10. A bowed instrument according to claim 9, characterized in that the spacer element or spacer elements (26) are shaped like bars, with a recess designed to receive strings (14) made on one of their side surfaces. 11. A bowed instrument according to any one of claims 1 to 10, characterized in that the string (14) located between the tailpiece (16) and the curl (8) of the neck (1) has the length indicated in the table: Tool String name Overall Length (mm) String B length of twisted section above the bottom button (mm): length of the metal twisted section of the string intended for playing (mm): length of the upper twisted section for winding on a peg (mm) Violin G 510-680 10-30 400-500 100-150 D 580-700 10-30 470-520 100-150 A 600-740 10-30 470-530 120-180 E 540-660 10-30 450-500 80-130 Alto WITH 645-795 15-35 530-600 100-160 G 685-820 15-30 540-620 130-170 D 735-835 15-35 570-620 150-180 A 675-795 15-35 530-590 130-170 Cello WITH 1140-1235 40-60 960-1010 140-165 G 1150-1240 40-60 970-1020 140-160 D 1190-1290 40-60 970-1020 180-210 A 1180-1260 40-60 950-980 190-220 Double bass E 1880-1950 50-70 1600-1630 230-250 A 2020-2095 50-70 1640-1665 330-360 D 2050-2115 50-70 1650-1675 350-370 G 2010-2725 50-70 1650-1675 310-340 -