RU2087947C1 - Classic string musical instrument - Google Patents

Abstract

FIELD: musical instruments. SUBSTANCE: invention may find use in manufacture of classic string or pizzicato musical instruments. Special feature of invention lies in that one support of bridge on which strings rest is made elongated, is passed through hole made in upper sounding board at point of position of this elongated support, is placed in resonating space and rests with its butt against inner surface of lower sounding board. In this case angle of break of strings formed above bridge amounts to 165-177 deg. EFFECT: facilitated manufacture of musical instruments. 8 cl, 5 dwg

Description

 The present invention relates to the construction of stringed musical instruments and can be used in classical stringed bowed or plucked musical instruments of the violin or guitar family, as well as in folk instruments such as balalaika.

 In classical stringed musical instruments of the violin family, for example, the well-known Stradivarius violin (Great Soviet Encyclopedia. M. Soviet Encyclopedia, 1976, v. 23, p. 1575), a set of strings are used that are pulled with the help of pegs in the head of the instrument towards the fixture to secure the strings over the bridge located on the top deck. The bridge has left and right supports. In the resonating cavity, a sound stand is located somewhat behind the right support between the upper and lower decks, designed to perform the function of a phase regulator between these decks.

 However, with the indicated structural arrangement of the sound stand, the energy of sound from the upper deck is forced to pass to the lower deck in a winding way, as a result of which this energy is lost, the power and brightness of the sound of the instrument are reduced.

 Over the many years of the evolution of stringed bowed instruments, an increase in the power and brightness of their sound was achieved by increasing the tension of the strings by increasing the height of the bridge, as well as by replacing the vein strings with metal ones.

 In old instruments such as the Stradivarius violin, the thickness of the upper (spruce) and lower (maple) decks, due to the acoustic properties of the wood, is optimal, however, with increased initial statistical loads, the case becomes mechanically overstressed at these thicknesses of decks, which negatively affects the timbral properties and sensitivity of the instrument .

 Thus, it turned out that an increase in the power of an instrument without improving its design as a mechanical system leads to a loss of the qualitative characteristics of the sound of the instrument, that is, to a deterioration in the overtone fullness (timbre), and an increase in the uneven sound of individual strings.

 The construction of the well-known classical stringed musical instruments of the guitar family is similar to the construction of the violin family described above. In this case, the bridge supporting the strings is placed on the upper deck with its entire lower plane, that is, the right and left supports of the bridge are made in one piece. During the excitation of the strings, the vibrational forces from them through the bridge are transmitted directly only to the upper deck, while the lower deck remains a passive element to which the vibrational forces are transmitted through the shells, that is, significantly weakened.

 In the classical design of the guitar (P. Agafoshin. School of playing the six-stringed guitar. M. Muzyka, 1983, p. 6, 7), the bridge on which the strings rest is rigidly bonded to the upper deck with its entire lower plane. At the same time, he transfers to this deck mainly longitudinal vibrations from sounding strings, which are only indirectly (through the entire body) converted into transverse vibrations of the decks necessary for resonant amplification of sound. Unlike bowed instruments, the guitar body is not mechanically overstretched, however, due to the lack of direct conversion of string vibrations into lateral vibrations of decks, the initial prerequisites for the operation of the guitar body as a resonator are even less favorable than for a bowed instrument. These factors do not make it possible to optimally use the resonating properties of the wood and the guitar body itself, as a result of which the maximum sound power, brightness and sensitivity of the instrument are not achieved.

A classic string musical instrument is known (US patent N 4867029, September 19, 1989, selected by us for the prototype), containing a body including a shell, upper and lower decks, forming a resonating cavity. On one side of the case there is a neck equipped with a head with pegs for tensioning the strings, and a neck over which these strings are stretched, and on the other hand
a device for securing strings stretched between the pegs and a device for securing strings over the upper deck, on which a bridge supporting the strings is located, located transversely to the arrangement of strings pressing it in a direction perpendicular to the surface of the upper deck. The bridge has right and left supports (when viewed from the side of the head). Directly under the right support in the resonating cavity there is a sound stand, which with its ends fits snugly on the inner surfaces of the upper and lower decks. The longitudinal axis of the neck is made at an acute angle to the longitudinal axis of the body. A device for securing strings includes a subheading, a rod for securing a loop that has two parallel threads, and a device for changing the angle of a string fracture formed above the bridge, containing many massive elements designed to make the bridge bisect the angle of the string fracture.

 It is believed that the presence of a sound stand and the use of symmetrical angles can improve the sound, brightness and sensitivity of the instrument in the entire range of its sound.

 However, this constructive implementation is only able to slightly increase the sound power of the instrument, since the presence of a massive unit, due to which the alignment of angles between the strings over the bridge is achieved, is at the same time a mute (silencer) that absorbs a significant part of sound energy.

 In addition, the rotational (torsional) component that is present in the oscillations of the bridge, along with vertical reciprocating movements, which turns into internal spurious stresses in the upper deck and in the bridge and also leads to loss of sound energy, remains practically unrealized.

 The basis of the present invention is the task to create a classic string musical instrument with such a constructive implementation of its elements, which would increase the sound power, brightness and sensitivity of the instrument.

This problem was solved by creating a classical string musical instrument containing a body, including a shell, upper and lower decks, forming a resonating cavity, and having on one side a neck equipped with a head with pegs for tensioning the strings, and a neck over which these strings are stretched, and with of the opposite side for securing strings, including a neckline, to one end of which an elastic loop is rigidly attached, resting on a device for changing the angle of fracture of strings placed on the upper deck, and is worn on a rod mounted on the shell under the device for changing the angle of the string fracture, and to the other end of the subheading strings are rigidly attached, stretched over the upper deck, on which there is a bridge supporting the strings, having two supports and located transversely to the arrangement of strings, pressing it in the direction perpendicular to the surface the upper deck, on the outer surface of which one buttress of the bridge rests with its end face, while, according to the invention, an opening is made in the location of the second bridge support in the upper deck moreover, this support is made elongated, passed through an opening in the upper deck, placed in a resonating cavity and rests on its face on the inner surface of the lower deck, while the angle of the string fracture formed above the bridge is 165-177 ^o .

 The proposed design provides an autonomous connection of each deck through a bridge with strings. In this case, symmetrical excitation of both deck decks is achieved, when each deck is excited at only one point, at the contact point of each bridge support with the corresponding deck. At the same time, the effect of the mute is excluded, and the resonant and timbral properties of the instrument material are used to the fullest. In addition, the proposed structural design of the tool allows you to create the necessary initial transverse forces on both decks from the tension of the strings. The same mechanism also works effectively in the dynamic mode with vibrating strings, transforming the reciprocating and rotational vibrations of the bridge into transverse vibrations of both decks simultaneously. In this case, due to an increase in the angle of fracture of the strings above the bridge, the initial static loads on the casing are reduced, and the dynamic effect on the casing from vibrating strings does not weaken, but increases, since it is transmitted directly from the bridge not only to the upper, but also to the lower deck, which becomes active resonating work element. In addition, the excitation of each of the decks at only one point allows you to convert the rotational component of the oscillations of the bridge into additional transverse vibrations of the decks, improving the resonant properties of the body and, therefore, increasing the sound power of the instrument.

 It is advisable that the elongated support was made hollow. A decrease in its mass reduces the absorption of kinetic energy due to inertia and, thereby, improves the resonant properties and sensitivity of the instrument.

 To enhance the sound power of the instrument in the upper range, it is desirable that the elongated support was made on the left side of the head.

 To enhance the sound power of the instrument in the lower range, it is favorable that the elongated support is made on the right side of the head. The timbre of the upper range is softened.

 It is advisable that the elongated support was made integral along the length and its component parts were articulated together approximately at the level of the top deck. The presence of a swivel eliminates the parasitic internal elastic stresses in the elongated support resulting from rotational vibrations of the bridge, which increases the sound power of the instrument.

It is advisable that the angle γ between the longitudinal axis of the neck and the longitudinal axis of the body is 180 - (α + β) ^o , where:
α the angle of fracture of the strings through the bridge,
b the angle between the longitudinal axis of the graph and the longitudinal axis of the strings located above the neck, equal to 1-3 ^o .

 Such a constructive implementation provides the creation of a given angle of fracture of the strings without a significant increase in the mass of the elements of the device for changing this angle.

It is desirable that the device for changing the angle of fracture of the strings is a nut mounted on the upper deck at the place of its junction with the shell on the opposite end of the head and having a height that provides the creation of an angle of fracture of the strings 165-177 ^o .

 Such a constructive implementation can significantly reduce the mass of the specified device, which significantly reduces the effect of the mute, and therefore increases the sound power of the instrument. In addition, this allows you to adjust the initial voltage during the manufacturing process of the tool.

 It is favorable that in the area between the place of attachment of the loop to the neck and the place of contact of the loop with the nut, the two threads of the loop are fastened together. This allows maximum use of the rotational component of the bridge oscillations, most fully transforming it into transverse sound vibrations of the decks, which increases the power, brightness and sensitivity of the instrument.

In FIG. 1 shows a general view of a violin, a longitudinal section;
in FIG. 2 cross section AA in FIG. 1, with breakouts;
in FIG. 3 place B in FIG. 1, top view;
in FIG. 4 general view of the guitar, isometry;
in FIG. 5 section BB in FIG. 3.

 A classical stringed musical instrument, for example, a violin (Fig. 1, 2, 3), made according to the invention, comprises a casing 1, including a shell 2, an upper deck 3, a lower deck 4, forming a resonating cavity 5. A neck 6 is located on one side of the casing 1 equipped with a head 7 with pegs 8 for tensioning the strings 9, and a neck 10, over which these strings are stretched 9. On the opposite side of the housing 1 there is a device for securing strings 9, stretched between the pegs 8 and the device 11 for securing the strings 9 over the upper deck 3 , on which a bridge 12 supporting the strings 9 is located, located transversely to the arrangement of the strings 9, pressing it in a direction perpendicular to the surface of the upper deck 3.

 The bridge 12 has two supports 13, 14. One, for example, the right one, the support 13 of the bridge 12 (when viewed from the side of the head 7) rests with its end on the outer surface of the upper deck 3. At the location of the second (left) support 14 of the bridge 12 in the upper On deck 3, a hole 15 is made, while the left support 14 is elongated, passed through the hole 15, placed in the resonating cavity 5 and rests on its face on the inner surface of the lower deck 4. In this design, the lower maple deck 4 becomes the active resonating element and the source com higher than the upper spruce deck of 3 3 overtones. As a result of this, the connection of the left support 14, over which the soprano string 9 is located, gives the upper register a greater brightness. This location of the elongated support 14 is suitable for solo instruments. Moreover, in the resonating cavity 5 on the inner surface of the upper deck 3 immediately below the right support 13, a spring 16 is rigidly fixed, designed to mechanically strengthen the upper deck 3.

 If necessary, to enhance the sound power of the instrument in the lower elongated range, the right support can be made. Since with a standardly matched pair: maple for the lower deck 4, spruce for the upper deck 3, maple has a higher overtone color, the connection of the right support (if it is extended), above which the bass string is located, with the lower deck 4 will be larger add to the lower strings of high overtones, increasing the brightness of their sound. This arrangement of the elongated support is more suitable for ensemble and orchestral, mainly accompanying instruments. The spring 16 under the upper deck 3 in this case should be moved to the opposite side, symmetrically with respect to the longitudinal axis of the tool.

 To reduce mass, the elongated support 14 is hollow. This increases the sensitivity of the instrument as a resonator. In this case, the elongated support 14 is made lengthwise and its components are pivotally interconnected approximately at the level of the upper deck 3. The presence of a swivel eliminates spurious internal elastic stresses in the elongated support 14 resulting from rotational vibrations of the bridge 12, which increases the sound power of the instrument .

 As described above, the strings 9 are stretched over the upper deck 3, on which the bridge 12 supporting the strings 9 is placed, and fixed on the opposite end of the housing 1 by means of a device 11 for securing the strings 9.

In the place of contact of the strings 9 with the bridge 12, the strings 9 have a fracture angle of 165-177 ^o . It was experimentally established that the specified angle a of the fracture of the strings 9 through the bridge 12 is sufficient to create the necessary initial pressure on the upper and lower decks 3, 4 and for optimal operation of the housing 1 in dynamic mode. If the angle a is greater than 177 ^{o, the} initial pressure is not enough, and too flabby strings 9 cannot excite the housing 1 to the necessary degree. Because of this, the sound power of the instrument decreases, the sound turns out to be dull, lethargic. When the angle is less than 165 ^{o, the} housing 1 becomes overstressed, which, as mentioned above, leads to a loss of quality characteristics of sound.

The creation of the specified angle a of the fracture of the strings 9 can be achieved if the angle g between the longitudinal axis of the neck 6 and the longitudinal axis of the body 1 is 180 - (α + β) ^o , where:
α angle of string fracture 9,
b the angle between the longitudinal axis of the neck 6 and the longitudinal axis of the strings 9 located above the neck 6, equal to 1-3 ^o .

 The device 11 for securing the strings contains a device for changing the angle of fracture of the strings, which is a nut 17 mounted on the upper deck at the junction with the casing 2 at the end opposite to the head 7. In addition, the device 11 for securing the strings 9 contains a subheading 18, At one end of which strings 9 are rigidly attached, and at the other end is a metal or core loop 19, which rests on the nut 17. By adjusting the height of the nut 17, you can change the angle of fracture of the strings 9 through the bridge 12. The same effect can be achieved adjust the height of the bridge 12.

 A fastener 20 is placed under the nut 17 in the resonant cavity 5, rigidly connecting the upper deck 4 and the shell 2. A through hole is made in the shell 2 and the fastening element 20, the axis of which is parallel to the longitudinal axis of the housing 1. A wooden rod 21 with a hat 22 is installed in this hole , on which the loop 19 is worn. In this case, on the section between the place of fastening of the loop 19 to the neck 18 and the place of contact of the loop 19 with the nut 17, two threads of the loop 19 are fastened together, for example, crossed. As a result of this, the counteraction to rotational vibrations of the sub-section 18 becomes minimal and the sub-section 18 becomes a more active inertial element, which contributes to the conversion of the kinetic energy accumulated during the excitation of the strings 9 into the rotational vibrations of the bridge 12 and through it into the sound vibrations of Dec 3, 4 in the mode free attenuation.

 For instruments such as a guitar, where the duration of the sound depends precisely on the decay time of the vibrations of the strings 9 after pinching in free mode, this design significantly improves the sensitivity and resonance properties of the instrument. For bowed instruments, this improvement is manifested primarily when playing with tweezers (pichichato). At the same time, the spring 16 under the upper deck 3, which, contrary to the acoustic properties of the instrument, was required to be massive enough to give the upper deck 3 the necessary strength, with this constructive design of the loop 19, can be reduced in mass, which improves the sensitivity of the instrument and reduces the effect of the mute that arises from any parasitic mass.

 To connect the resonating cavity 5 with the surrounding space in the upper deck 3, holes 23 are made.

 A classic plucked string instrument, for example, a guitar (Fig. 4, 5), made according to the invention is structurally similar to the violin described above, with the only difference that in plucked instruments the neck 10 is parallel to the surface of the upper deck 3, and the body 1 is not subject to an unnecessary initial stress. In addition, the location of the springs 16 on the upper and lower decks 3, 4 is usually symmetrical about the longitudinal axis of the tool, so there is no need to change the location of the installation.

 The embodiment according to the invention can be used in any other stringed or plucked musical instruments, such as cello, viola, double bass, as well as in any stringed folk musical instruments, for example, balalaika, domra, mandolin, which differ from each other only in shape elements, and in fact are similar tools, the case of each of which acts as a resonator.

 For the manufacture of the proposed musical instruments, as a rule, the following materials are used: spruce for the upper deck and springs, maple for the lower deck, shell, neck, head, bridge, ebony (ebony) for the neck, neck, pegs, rod, nut. The strings are metal or core. By adjusting the height of the bridge, the height of the nut and the angle g during the manufacture of the tool, the angle of string fracture is created in a given range.

 From the excitation of the strings 9 with a bow or a pinch, the elastic vibrations are transmitted to the body 1: through the rod 21, pierce 17, the place of attachment of the neck 6 to the body 1 (longitudinal vibrations), through the bridge 12 (transverse vibrations) directly to the upper deck 3 and the lower deck 4. Oscillations of the housing 1 excite oscillations of the internal volume of air located in the resonating cavity 5, which, being connected with the external space through the hole 23 in the upper deck 3, becomes a source of sound propagation outside. Using the present invention increases the sound power of the instrument while increasing the brightness of the sound and the sensitivity of the instrument.

Claims (8)

1. A classic stringed musical instrument containing a shell, including a shell, upper and lower decks, forming a resonating cavity and having on one side a neck equipped with a head with pegs for tensioning the strings, and a fingerboard over which these strings are stretched, and on the opposite side
a fixture for securing strings, including a neck plate, to one end of which an elastic loop is rigidly attached, resting on a fixture for changing the angle of fracture of the strings, placed on the upper deck and worn on a rod mounted on the shell under the fixture for changing the angle of fracture of the strings, and to the other end the strings are stiffly attached strings extending over the upper deck, on which a bridge supporting the strings is placed, having two supports and located transversely to the arrangement of strings pressing it into a board perpendicular to the surface of the upper deck, with one end resting on the outer surface of the upper deck, characterized in that a hole is made in the location of the second bridge support in the upper deck, this support is elongated, passed through the hole in the upper deck, placed in resonating cavity and its end rests on the inner surface of the lower deck, while the angle of fracture of the strings formed above the bridge is 165 177 ^o .  2. The tool according to claim 1, characterized in that the elongated support is made hollow.  3. The tool according to claims 1 and 2, characterized in that the elongated support of the bridge is made on the left side relative to the head.  4. The tool according to claims 1 and 2, characterized in that the elongated support of the bridge is made on the right side of the head.  5. The tool according to claims 1 to 4, characterized in that the elongated support is made integral along the length and the components of the support are pivotally interconnected approximately at the level of the upper deck. 6. The tool according to claims 1 to 5, characterized in that the angle between the longitudinal axis of the neck and the longitudinal axis of the body is 180 - (α + β) ^° , where α is the angle of fracture of the strings, β = 1 - 3 ^° is the angle between the longitudinal axis neck and the longitudinal axis of the strings located above the neck. 7. The tool according to claims 1 to 5, characterized in that the device for changing the angle of fracture of the strings is a nut mounted on the upper deck at the place of its junction with the shell on the opposite end of the head and having a height that provides the creation of an angle of fracture of the strings 165 177 ^o .  8. The tool according to PP.1 to 7, characterized in that in the area between the place of attachment of the loop to the end plate and the place of contact of the loop with the nut, two threads of the loop are fastened together.

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