Tone and playing response adjuster for stringed musical instruments

Abstract

This invention comprises a novel mechanical system for adjusting downward and side-to-side pressure of strings on the bridge of stringed musical instruments. The system comprises a threaded female element, to which an instrument's tailgut is attached, and a threaded mounting bolt which freely spins in a socket joint, which is incorporated into a mounting bracket secured to the instrument's end block, thereby allowing the tailgut's position at the point of the saddle to be adjusted higher, lower, or side-to-side relative to the instrument's table. These features allow the instrument's volume, resonance, and playing response to be adjusted in small increments, without detuning the instrument, to allow musicians to adapt quickly to different environmental playing conditions and musical repertoire.

Claims

1. A tone and playing response adjusting device for a stringed musical instrument of the type in which the strings extend over a bridge resting on the table of the instrument and are secured to a tailpiece, comprising adjustable means to change the downward and side-to-side pressure exerted by the strings on the bridge of said instrument, thereby adjusting its tone and playing response, without changing the musical pitch of the strings, wherein the downward and side-to-side tension of the strings on the bridge are controlled by moving a secondary saddle component, to which the instrument's tailgut is attached, which rests on the instrument's primary saddle and can be adjusted in four directions (higher, lower, or side-to-side) along a plane perpendicular to the table of the instrument, by means of a rotating mounting bolt and rotating mounting bracket assembly attached to the end block of the instrument.

2. A tone and playing response adjusting device for stringed instruments, according to claim 1, wherein the downward string tension adjusting means comprises a rotating bolt and nut assembly which acts as a lever when attached to the mounting bracket assembly, with the instrument's saddle acting as a fulcrum, thereby reducing torque on the end block of said instrument.

3. A tone and playing response adjusting device for stringed instruments, according to claim 1, wherein the mounting bracket assembly rotates in a hole in the end block of the instrument and is held in place against the pulling force of the mounting bolt by means of a lock nut.

4. A tailpiece and end block mounting bracket assembly for a stringed musical instrument where said assembly has a tone and playing response-adjusting device, according to claim 1, integrated into its construction.

5. A stringed musical instrument that has a tone and playing response-adjusting device, according to claim 1, integrated into its construction.

6. A tone and playing response-adjusting device for a stringed musical instrument, according to claim 1, wherein the downward pressure exerted by the strings on the bridge of said instrument is adjustable, but the side-to-side pressure is not adjustable.

7. A tone and playing response-adjusting device for a stringed musical instrument, according to claim 1, wherein the side-to-side pressure exerted by the strings on the bridge of said instrument is adjustable, but the downward pressure is not adjustable.

8. A tone and playing response adjusting device for a stringed musical instrument, according to claim 1, wherein the instrument's strings attach directly to the secondary saddle component.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1:

(2) Front view of a cello showing an overview of the location where the invention presented in this document contacts the body of the instrument

(3) FIG. 2:

(4) Closer view of the invention as it attaches to a cello

(5) FIG. 3:

(6) Interior view of the invention

(7) FIG. 4:

(8) Side view of invention showing how it is inserted through a hole in an instrument's end block

(9) FIG. 5:

(10) View of a violin showing alternative design of the invention for violins and violas

(11) FIG. 6:

(12) View of a traditional stringed instrument tailgut as it wraps around the end button for reference to prior art

DETAILED DESCRIPTION OF THE INVENTION

(13) This invention comprises a mechanical system for raising or lowering downward pressure of strings on the bridge of musical instruments in the violin family (violins, violas, cellos, and double basses), as well as other stringed instruments that operate in a mechanically similar manner. With reference to FIG. 1, the aforementioned stringed instruments create sound via strings (9) attached to pegs (2) in a pegbox (3) at the head or scroll of the instrument (1). The tightened strings travel over the fingerboard (6) and bend over a bridge (8) before attaching to the tailpiece (10). The tailpiece, in turn, connects to the body (4) of the instrument via a tailgut (12) made of strong cord or wire which passes over the saddle (11), which is a piece of hardwood or hard plastic designed to support significant tailgut pressure and abrasion. The saddle is traditionally glued to the instrument's interior end block as shown in FIG. 4 (22). Because these instrument parts, and others, are subject to expansion and contraction with environmental expansion and contraction due to temperature and humidity changes, the angle of the strings over the bridge is in a perpetual state of change. This change, albeit subtle, is enough to affect the tone and playability of the instrument from day to day. By allowing the angle of the strings over the bridge to be adjusted in four directions (higher, lower, or side-to-side along a plane perpendicular to the table of the instrument), this invention allows the tone of the instrument to be changed in small increments. Relative to the top, or table, of the instrument which supports the bridge, the higher the tailgut is adjusted (resulting in strings bending less over the bridge and applying less downward pressure), the more resonant the tone of the instrument and the more agile the playing response. As the tailgut is adjusted downward towards the table, the instrument projects with more power and focus. Side-to-side adjustments change the relative bass and treble tone and playing response of the instrument.

(14) This invention accomplishes directional adjustability of the tailgut through an assembly of components comprising: A threaded female component, or saddle rider (15), that rests on the lower edge of an instrument's saddle to which an instrument's tailgut is attached; A saddle rider mounting bolt (16) that secures the saddle rider to the instrument's specially-designed end button, endpin mount, or a similar mounting; A modified endpin mount, end button, or similar saddle rider mounting bracket (17) specially designed to secure the end of the saddle rider mounting bolt and to allow it to rotate freely; and a mounting bracket locknut assembly (21), which holds the saddle rider mounting bracket securely in the instrument's end block, while allowing the mounting bracket to rotate from side to side. Additional bass and treble adjustability is created by extra tailgut holes (15A), which allow the tailpiece to be attached at varying angles favoring an instrument's treble or bass register.

(15) A key aspect of the efficient functioning of this invention is the manner in which the saddle rider component (15), rests on the underside of an instrument's primary saddle (11) with a very small contact area, thereby allow the table of the instrument to vibrate freely when played. Because an instrument vibrates relatively little at the corners (7) and end block (22), where interior blocks of wood support glue joints holding the instrument together, these areas can be touched while an instrument is played without muting the sound. Care should be taken, when installing this invention, that the instrument has a well-constructed and properly glued saddle, and that the saddle rider assembly (13) does not contact the body of the instrument anywhere other than the saddle, which is designed to bear the tailgut pressures which range from 55-280 pounds in violin-family instruments.

(16) In order to install the saddle rider mounting bracket on an instrument without requiring the removal of the instrument's top, there are different procedures for the violin and viola version (FIG. 5), and the cello and double bass version (FIGS. 2-4). For violins and violas, the mounting bracket locknut assembly is taped to a flexible cord inserted through the end block hole and the instrument's F hole (5). Pulling out the cord then pulls the locknut assembly into place by inserting it through the end block hole. For cellos and double basses, which require an endpin (14) and endpin locking screw (18) for support, the specially-designed mounting bracket locknut assembly has a weighted L-shaped locknut. For installation, the locknut is rotated over the plug portion of the assembly to allow easy insertion into the end block hole. Once the mounting bracket assembly is inserted into the hole, the instrument can be set on its back on a table, causing gravity to toggle the L-shaped nut into position for tightening the locking bolt head (19) to rotate the locking bolt (20), thereby securing the assembly in the end block.

(17) The differing installation procedure for violins and violas is a result of the varied design of the saddle rider assembly for those instruments. This design variation is required because violins and violas are held under the player's chin via a chinrest (23). To give the player as much chin clearance as possible, the violin and viola version of the saddle rider assembly employs an Allen bolt (25) with the bolt head behind the violin and viola mounting bracket (24). To more clearly demonstrate the novel functioning of the saddle rider assembly, a traditional mounting of the tailgut (26) over a traditional end button (27) is shown in FIG. 6.

(18) With regard to the preferred embodiment of this invention, during research and development I have successfully crafted versions out of a variety of materials including wood, metal, and plastic. Because the saddle rider assembly is installed where little vibration occurs, the acoustical differences between the materials are relatively minor. A primary manufacturing consideration is to construct the invention in a way that protects the valuable musical instrument on which it may be installed from accidental damage due to breakage of the saddle rider or its mounting bracket. For constructing these two components, I prefer plastics with high tensile strength, abrasion resistance, and an elongation modulus before fracture of at least 6 percent in all directions. Plastics with these properties tend to offer slight acoustical resonance advantages over metal, wood, and stiffer plastics, and are less likely to fracture unexpectedly if subjected to accidental shocks like those that might occur if an instrument is dropped. The saddle rider assembly's plastic components can be manufactured through injection molding, CNC, or 3D printing (although current iterations of FDM 3D printing technology should generally be avoided because of irregular elongation modulus and tensile strength characteristics in the X, Y, and Z axis). The saddle rider mounting bolt can be manufactured with excellent durability from stainless steel. Mounting bracket T or L nuts may be successfully manufactured out of brass, steel, or titanium. Although plastic T or L nuts may function properly in the short term, because the stakes are high involving valuable stringed instruments, engineering the L and T nut out of brass, steel, or titanium is suggested for long-term durability. The invention will not work properly if the mounting bolt deflects even slightly, so care should be taken to select a mounting bolt with sufficient tensile strength to prevent deflection when subjected to the cumulative string tensions involved (55-280 pounds, depending on the instrument in question).