N/A
The invention relates to a stringed instrument; more particularly, the invention relates to violin instrument.
A violin is a wooden string instrument. Most violins have a hollow wooden body. A violin generally consists of a spruce top (the soundboard, also known as the top plate, table, or belly), maple ribs and back, two end blocks, a neck, a bridge, a soundpost, four strings, and various fittings, optionally including a chinrest, which may attach directly over, or to the left of, the tailpiece. A distinctive feature of a violin body is its hourglass-like shape and the arching of its top and back. The hourglass shape comprises two upper bouts, two lower bouts, and two concave C-bouts at the waist, providing clearance for the bow. The sound of a violin depends on its shape, the material it is made from, the graduation (the thickness profile) of both the top and back, and any coatings on its outside surface.
The violin includes four strings. The strings are usually tuned in perfect fifths with notes G3, D4, A4, E5. A violin is played by drawing a bow across the strings. It can also be played by plucking the strings with the fingers and by striking the strings with the wooden side of the bow.
Historically, finely handmade violins were made by hand. Violins produced by the Stradivari, Guarneri, Guadagnini and Amati families were prized collectors' items.
More recently, manufacturers mass-produced violins at lower costs. Beginners and novices commonly adopted these mass-produced violins. However, thee quality and sound of these mass-produced violins has been subject to criticism.
The present invention is provided to solve the problems discussed above and other problems, and to provide advantages and aspects not provided by prior stringed instruments of this type. A full discussion of the features and advantages of the present invention is deferred to the following detailed description, which proceeds with reference to the accompanying drawings.
One aspect of the present invention is directed to a string instrument comprising a body, a neck, and a tailpiece. The body comprises a top plate joined to a bottom plate forming an interior volume therebetween. The neck is attached to the body and extends outwardly therefrom. The tailpiece is joined to the body. The body further comprises a first soundpost within the interior volume joining the top plate with the bottom plate and a second soundpost within the interior volume also joining the top plate with the bottom plate.
This aspect of the invention may include one or more of the following features, alone or in any reasonable combination. The string instrument may further comprise a bridge extending upwardly from the top plate between the neck and the tailpiece and over which each string in a plurality of strings is tensioned wherein the neck has a top nut on an end opposite an opposing end attached to the body, wherein a plurality of strings engage the top nut and extend down a length of the neck towards the tailpiece, wherein the first and second soundposts are in alignment with the bridge and located below edges thereof. The first and second soundposts may be in mirror relationship relative to a vertical axis which passes down a length of the neck bisecting the body along longitudinal and transverse directions. The top nut and the tailpiece may be configured such that a distance from the tailpiece to the bridge is 1/6 a distance of the top nut to the tailpiece. A length and an angle of the neck may be configured to position an upper surface of the bridge 22 mm above the top plate. The top nut may further comprise a plurality of open-top string guides configured to receive strings therein. The string instrument may further comprise a tuner box joined to the neck opposite the body, the tuner box having a tuner bed having a plurality of apertures formed therein through which a corresponding plurality of tuners extend, the tuner bed configured to orient a first pair of strings at a first angle between 16° and 25° as measured from the tuner to the top nut upwardly from an axis parallel to the vertical axis of the string instrument and orient a second pair of strings at a second angle between 12° and 20° as measured from the tuner to the top nut upwardly from the axis parallel to the vertical axis. The first angle may be 21°±3° and the second angle may be 15°±2°.
Another aspect of the present invention is directed to a string instrument comprising a body, a neck, and a tailpiece. The body comprises a top plate joined to a bottom plate forming an interior volume therebetween. The neck is attached to the body and extends outwardly therefrom. The tailpiece is joined to the body. A bridge extends upwardly from the top plate between the neck and the tailpiece and over which each string in a plurality of strings is tensioned wherein the neck has a top nut on an end opposite an opposing end attached to the body, wherein a plurality of strings engage the top nut and extend down a length of the neck towards the tailpiece, wherein the top nut and the tailpiece are configured such that a distance from the tailpiece to the bridge is 1/6 a distance of the top nut to the tailpiece.
Another aspect of the present invention is directed to a string instrument comprising a body, a neck, and a tailpiece. The body comprises a top plate joined to a bottom plate forming an interior volume therebetween. The neck is attached to the body and extends outwardly therefrom. The tailpiece is joined to the body. A bridge extends upwardly from the top plate between the neck and the tailpiece and over which each string in a plurality of strings is tensioned wherein the neck has a top nut on an end opposite an opposing end attached to the body. The plurality of strings engage the top nut and extend down a length of the neck towards the tailpiece, wherein a length and an angle of the neck are configured to position an upper surface of the bridge 22 mm above the top plate.
Another aspect of the present invention is directed to a string instrument comprising a body, a neck, and a tailpiece. The body comprises a top plate joined to a bottom plate forming an interior volume therebetween. The neck is attached to the body and extends outwardly therefrom. The tailpiece is joined to the body. A bridge extends upwardly from the top plate between the neck and the tailpiece and over which each string in a plurality of strings is tensioned wherein the neck has a top nut on an end opposite an opposing end attached to the body. The plurality of strings engage the top nut and extend down a length of the neck towards the tailpiece. A tuner box is joined to the neck opposite the body. The tuner box has a tuner bed having a plurality of apertures formed therein through which a corresponding plurality of tuners extend. The tuner bed is configured to orient a first pair of strings at a first angle between 16° and 25° as measured from the tuner to the top nut upwardly from an axis parallel to a vertical axis of the string instrument and orient a second pair of strings at a second angle between 12° and 20° as measured from the tuner to the top nut upwardly from the axis parallel to the vertical axis.
The aspects of the invention may include one or more of the following features, alone or in any reasonable combination. The body and the tailpiece may be of a single body construction, wherein the body and the tailpiece are integrally formed from a single piece of material. The body and the neck may be produced via additive manufacturing. The string instrument is a violin. The neck and the body may be produced from a polymeric material. The neck and the body may be produced from a polylactic acid.
Other features and advantages of the invention will be apparent from the following specification taken in conjunction with the following drawings.
To understand the present invention, it will now be described by way of example, with reference to the accompanying drawings in which:
While this invention is susceptible of embodiments in many different forms, there is shown in the drawings and will herein be described in detail preferred embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the broad aspect of the invention to the embodiments illustrated.
Referring generally to the figures, two complete embodiments of a string instrument are illustrated. The first embodiment is illustrated in
Referring to
The body 14 has a roughly hourglass shape. An upper bout 22 is separated from a wider lower bout 26 by a center bout, or waist, 30. The center bout 30 is generally narrower than the upper and lower bouts 22,26. A top plate 34 is joined to a back plate 38 by a rib 42 which forms a side wall of the violin 10. This construction forms an interior volume 46 within which a soundposts 50a,b rigidly span interior surfaces of the top and back plated 34,38 (see, e.g.
The top plate 34 has a pair of openings 54 located on opposing sides of the plate 34. The openings 54 are generally s-shaped or f-shaped and are located primarily within the center bout 34 and extend into the lower bout 26. The openings 54, combined with the interior volume 46 promote resonance of the violin 10 when played.
The top plate 34 further has a tailpiece 58 forming a raised surface. The tailpiece 58 has four string bores 62 which are used to attach strings 20 to the body 14 (see, e.g.,
The tailpiece 58 structure comprises a shell wall which defines a volume between the shell and the top plate 34. Additive manufacturing infill fills the volume to provide strength, and rigidity to the tailpiece 58.
Pairs of the string bores 62 have string entrances 63a to the tailpiece 58 along opposing sidewalls of the tailpiece 58 shell. The string bores 62 form aligned string exits 63b on a front face of the tailpiece 58 shell. The string bores 62 have variably sized cross-sections to retain ball ends of the strings 20 within the string bores 62. Stated another way, the string entrances 63a have a greater cross-sectional size to allow the ball ends to enter the string bores 62 but the string bores' cross-sectional area decreases at some point at a throat 64 along each string bore length such that the ball ends frictionally engage string bore sidewalls to retain the ball ends within the string bores 62.
In an embodiment of the invention, the string bores 62 are tubes formed within the tailpiece 58. Further, the string bores 62 are shifted upward and each string bore throat 64 is located within the tail piece 58 which holds the ball-end at a specific location within the tail piece 58 such that string bores 62 are fully covered and the tailpiece 58 becomes more stable with less extra input resonance from the thin walls of prior designs.
In one embodiment, the string bores 62 are positioned wherein the string bores 62 all change diameters at substantially a same height above the top plate 34. Each throat 64 has an entry end 64a and an exit end 64b. The cross-section areas of each string bore 62 begin to decrease between the entry end 64a and the exit end 64b of each throat 64. In one embodiment, the cross-sectional areas progressively decrease from the entry end 64a to the exit end 64b. A short tubular segment 62a of each string bore 62 joins each throat 64 to the string exits 63b. Here, the term substantially refers to within ±1 mm.
With some violins 10 produced using additive manufacturing, the string placement on is uneven and much wider than any handmade or traditional violin. In one embodiment of the invention, a spacing between the strings 20 is uniform and fits on a standard 1/4-size bridge 65. The string bores 62 of this embodiment are out-of-round at least at the string exits 62b of the tailpiece 58 and preferably have an oval cross-section having a minor axis normal to a plane defined by an upper surface 66 of the tailpiece 58 and a major axis parallel to the plane. These string exits 62b of the string bores 62 allow the strings 20 to shift as the strings 20 are placed into tension such that the strings 20 land optimally on the bridge 65 with minimal extra tension.
The bridge 65 is a decorative and functional member that balances underneath the strings 20 and transmits vibrations from the strings 20 into the body 14 of the violin to create sound. The bridge 65 of the violin 10 is not glued or attached to the body 14. Instead, the bridge 65 is held in place by a tension of the strings 20. The force that the strings 20 exert on the bridge 65 of a standard violin is equal to about 90 pounds.
In an embodiment, a height of the tailpiece 58 is selected lower than on prior designs produced from additive manufacturing. A standard violin has a nut-to-bridge-to-tailpiece ratio of 1/6 and a bridge length, measured from a top nut 86 (see below) and/or the tailpiece 58, is set based on the violin type. That is, a distance from the bridge 65 to the tailpiece is 1/6 a distance of the top nut 86 to the tailpiece 58. To meet the required ratio and maintain standard sizing, the tailpiece 58 extends towards the lower bout 26 downwardly on the body 14. In additive manufacturing. the downward movement had to insure printability and keep the string bores 62 correctly positioned within the tailpiece 58. Stated another way, The tailpiece is moved downwardly in a direction from the center bout 30 towards the lower bout 26 such that the tailpiece 58 is positioned to achieve the 1/8 to 1/6 ratio whereas prior violin design produced using additive manufacturing did not achieve the ratio because a length of the top nut to the tailpiece 58 was too short. A printability of overhangs was what was accounted for in setting the minimum height of the tailpiece 58 from a lowermost portion of the top plate 34. “Overhang” is a printing term for when something is building out on a layer smaller than it, like that of a building.
In one embodiment the nut-to-bridge-to-tailpiece ratio of and a bridge length, measured from a top nut 86 and/or the tailpiece 58, is less than or equal to %. In another embodiment, the ratio is less than %. In another embodiment, the ratio is greater than or equal to % and less than %.
The soundposts 50a,b are located inside the violin 10, under a right side of the bridge 65. One soundpost 50a is located below an E string side of the bridge 65, and the second soundpost 50b is located below a G string side of the bridge 65. The soundposts 50a, b transmit vibrations of the strings 20 into the body 14 of the violin 10 to create sound, and their placement can change the quality of that sound, in terms of volume and/or tone quality.
As best illustrated in
As illustrated in
As shown in
The neck 18 is separable from the body 14 and is attached to the body 14 via, at least, frictional engagement of a friction-fit of a button 79 within the notch 70. The button 79 is an appendage extending outwardly from a back of the neck 18 and transverse to the vertical axis. A top surface of the neck 18 forms a fingerboard 82 from the center bout 30 to a top nut 86. The top nut 86 includes string guides 88 to maintain alignment of the strings 20 above the fingerboard 82. The top nut 86 separates the fingerboard 82 from a tuner box 90. The tuner box 90 includes four tuners 94 which are rotatable within apertures. The strings 20 are wound about the tuners 94 to tighten and loosen the strings 20 as necessary to tune the strings 20 to make the desired sounds.
In an embodiment of the invention, an angle and length combination of the neck 18 is configured to provide 22 mm of height above the top plate 34 at the location of the bridge 65. An open-source additive manufacturing file of a violin neck was designed to be printed on a wide variety of machines; however, the neck length was drastically shorter than that of a traditional 1/4 size violin and therefore was missing more than an octave of notes. By changing the length, it added guidance for determining the appropriate neck angle as well as providing the ability to play all of the same notes as the wooden counterpart violin.
In a prior violin produced via additive manufacturing, strings 20 passed through holes in the top nut 86 rather than over the top of the top nut 86, and the violin had a much shorter neck extension over the upper bout 22 of the body 14. Thus, the ratio was not accurately determinable. Once the neck 18 length was made to be accurate to a 1/4 size violin and the top nut 86 was changed to be external, there were still acoustical issues, and the standard ratio of spacing between the top nut 86 to the bridge 65 distance, and the bridge 65 to tailpiece 58 distance of 1/6 was not being met. In one embodiment, an angle and length of the neck 18 angle is configured to position an upper side of the bridge 65 at 22 mm, and the tailpiece 58 is moved downwardly in the direction farther away from the center bout 30 and towards or along the lower bout 26, the 1/6 ratio could be obtained to within 1 mm and the majority of echoes and acoustic flaws were removed or diminished.
As described above, prior violins of this type produced via additive manufacturing featured uneven string spacing. This uneven spacing was designed to accommodate a neck central bore 98 and because the strings 20 were imbedded within the top nut 86. In an embodiment of the present invention, in order to fix the uneven tensions caused by differing angles from the strings 20 to the tuners 94, the string guide spacing is even and the tailpiece 58 orientations were changed to be the same shape and profile orientation to accommodate for the change to an exterior strung top nut/string interface. More specifically, the string exits 63a are oriented such that each string exit 63a is pointed towards a corresponding string guide 88 and the nut-to-bridge-to-tailpiece spacing is proper for a desired sized bridge, e.g. a 1/4 sized bridge.
Again, according to a prior art violin produced via additive manufacturing, the top nut 86 included holes through a block or body member to direct the strings 20 towards the tuners 94. This drastically increased tension in the strings 20 to where the strings 20 could not be stored in tension without snapping. By respacing the strings 20 so that the strings 20 are evenly spaced and by providing open-top string guides 88 on the top nut 86 with a straight path like a traditional 1/4 violin, the tension was dramatically decreased and the sound quality was increased due to the strings 20 no longer being constricted.
After the top nut 86 is adjusted to allow for the strings 20 to be exposed, the strings 20 have a tendency to slip due to a significant tension decrease. In an embodiment of the invention, a height of the top nut 86 was decreased and heights of the string guide walls were increased and configured to maintain a height of the strings 20 above the fingerboard 82 constant, wherein the string guides on the top nut 86 prevent string slipping. The top nut 86 is designed to be a height of 1.5-2.5 mm (different for different stringed instruments) and terminating at a height above the fingerboard 82 according to an equation:
where HTN is a height of the top nut 86 above the fingerboard 82, Dstring is a string diameter, ΔHTN→B is the minimum height of the top nut 86 above the bridge 65, and K is a correction factor between −0.5 mm to 0.5 mm, typically between 0 mm and 0.1 mm
Further to a known violin produced using additive manufacturing, the strings 20 have a tendency to slip and produce undesired sound quality due to an uneven tuner 94 distribution required for consistent 3D printing. In one embodiment, a depth of the tuners 94 is increased and a string angle γ1,γ2 (see, e.g.
The original purpose of the neck central bore 98 was to accommodate and a carbon fiber rod insert which increased violin stability; however, the insert causes a large increase in weight that is suboptimal. By removing the rod and changing the printing characteristics to be stronger and more durable, the neck central bore 98 can be modified to act as a resonance bore, which are known in violins produced from other materials. A cross-section of the central bore 98 has a circular shape having a diameter no less than 3 mm no greater than 10 mm. In one specific embodiment, the diameter of the central bore 98 is currently 4.0 mm.
The tuner box 94 has a tuner bed 102 having four apertures therein through which the tuners 94 extend to engage the strings 20. The tuner bed 102 is generally a block member having a rectangular cross-section both transverse and parallel to the vertical axis. The tuner bed 102 has a thickness sufficient to provide resistance strength against the tension of the strings 20. The minimum and maximum thicknesses of the tuner bed 102 are dictated by the specific tuners employed. The thickness typically will fall within a range of 12 mm to 20 mm, more preferably between 12 mm and 15 mm, and most preferably about 15 mm in the embodiment illustrated in
In a prior art violin produced using additive manufacturing, the tuner bed 102 thickness was at the maximum that standard tuners 94 could accommodate, and due to inconsistencies with manufacturing, some tuners 94 would be unable to be accommodated. In one embodiment of the invention, the tuner box 94 thickness is reduced by removing material from a bottom surface of the tuner bed 102 so as not to affect the tension and distance ratios on a top surface of the tuner bed 102 (See, e.g.,
In additive manufacturing, supports 106 are necessary to support the printing article, In a known prior violin produced via additive manufacturing, the design of the supports 106 were very thin and caused an instability when printed on non-Cartesian machines or machines with a moving build plate. The supports 106 are located adjacent and outwardly of the center bout 30 on opposite sides of the instrument body.
In an embodiment of the invention, a violin 10 produced via additive manufacturing is produced with supports with an increased lower support wall thickness which cradles the bottom of the chamber forming a bottom cradle 110, the stability was increased and the tipping risk on printing was dramatically reduced with no decreased in other quality features.
As illustrated in
While the specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention, and the scope of protection is only limited by the scope of the accompanying Claims.
This application claims the benefit of U.S. Provisional Patent Application No. 62/962,580, filed Jan. 17, 2020, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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62962580 | Jan 2020 | US |