The present invention relates to a string locking structure for an electric guitar, and particularly relates to a string locking structure for an electric guitar in which a string can be locked in two string-locking modes using a tailpiece.
In an electric guitar, e.g. a Les-Paul-type of guitar, a string is passed through a string through-hole formed in a tailpiece attached to the surface of a body, the end of the string, called the ball end, is hitched into the opening of the string through-hole, the other end of the string is wound around a peg in the head side, and the string is pulled taut with a predetermined amount of tension. The bridge disposed on the head side relative to the tailpiece has a function as a fulcrum of string oscillation when the string is plucked, a fine-tuning function of intervals tuned with the peg, a function of adjusting the height of the bridge itself in order to adjust the height of the string from the fret board, and other functions.
Patent Document 1 discloses a string locking structure for an electric guitar that uses a tailpiece. In Patent Document 1, strings are passed through holes formed in a fixed plate of a tremolo block, the ball ends of the strings are locked in portions of large inside diameters formed in the rear ends of the holes, and the fixed plate functions as a tailpiece. The holes for passing the strings through the fixed plate are linear through-holes extending from the front surface to the rear surface. Patent Document 2 discloses a string locking structure using a bridge having an integrated tailpiece, in which a string through-hole extending linearly in the longitudinal direction of the guitar is formed in the bridge.
[Patent Document 1] JP-A 2007-537471
[Patent Document 2] JP-A 2005-195954
A tailpiece used in order to lock the strings of an electric guitar in conventional practice commonly has a configuration in which six string through-holes are formed extending linearly in the longitudinal direction of the guitar, and there have been no proposals for a tailpiece having a function of locking a string in different string-locking modes, e.g. string-locking modes of different string length.
In view of these points, an object of the present invention is to provide a string locking structure for an electric guitar in which a string can be locked in two different string-locking modes using a tailpiece, and to provide a tailpiece suitable for configuring this string locking structure.
To solve the problems described above, according to the present invention, there is provided a string locking structure for an electric guitar in which the rear ends of a plurality of strings are locked using a tailpiece attached to a surface of a body of the electric guitar; the string locking structure characterized in that:
the tailpiece is formed with a plurality of first string passing paths that extend through the tailpiece and that are parallel to each other, and formed with a plurality of second string passing paths that extend through the tailpiece and that are parallel to each other;
the first string passing paths extend linearly from first front-end openings exposed in a front surface portion that faces toward the head of the electric guitar within the tailpiece, up to first rear-end openings exposed in a rear surface portion that faces the opposite direction from the front surface portion;
the second string passing paths extend at a curve from second front-end openings exposed in the front surface portion of the tailpiece up to second rear-send openings exposed in a bottom surface portion in contact with the surface of the body within the tailpiece;
the body is formed with a plurality of parallel body-side string through-holes leading from front surface openings exposed in the surface of the body to rear surface openings exposed in the rear surface of the body;
the front surface openings of the body-side string through-holes communicate with the respective second rear-end openings of the second string passing paths; and
the strings can be set to one of two string-locking modes: a first string-locking mode in which the strings are passed through the first string passing paths from the rear side of the tailpiece and ball ends on the rear ends of the strings are locked in the first rear-end openings of the first string passing paths, and a second string-locking mode in which the strings are passed sequentially through the body-side string through-holes and the second string passing paths from the rear surface side of the body and the ball ends in the rear ends of the strings are locked in the rear surface openings of the body-side string through-holes.
In the string locking structure for an electric guitar of the present invention, the strings can be locked in two string-locking modes; i.e., the second string-locking mode in which the strings are passed from the rear surface side of the body through the tailpiece attached to the front surface, and the first string-locking mode in which the strings are passed through and locked to the tailpiece similar to conventional practice. Because the body-side string through-holes formed in the guitar body are obscured by the tailpiece, the strings can be locked in the two string-locking modes without changing the appearance of the front surface of the guitar body.
It is sufficient merely to form the second string passing paths in the existing tailpiece provided with the first string passing paths and to form the body-side string through-holes in the body, and there is no need to manufacture or attach new components. Consequently, two string-locking modes can be achieved with a simple configuration without inducing large increases in manufacturing costs or manufacturing steps.
Furthermore, in the second string-locking mode, because the strings are passed through the body-side string through-holes formed in the body, string oscillation can be transferred more efficiently to the guitar body in comparison with the first string-locking mode in which the strings are locked to the tailpiece, whereby more harmonic overtones can be achieved.
Furthermore, the string length is longer in the second string-locking mode than in the first string-locking mode. Due to the second string passing paths being shaped so as to curve from the front surface portion of the tailpiece toward the bottom surface portion, a large amount of tensile force can be imparted to the strings by supporting the strings on the curved portions of the second string passing paths. As a result, when the guitar is tuned down, the strings can be maintained in a state of tension of greater tensile force in comparison to the first string-locking mode, and the tuned-down guitar can be played without stress.
It is simple to machine the holes when the second string passing paths are opened perpendicular to the first string passing paths, but the second string passing paths can also be formed so as to be inclined relative to the first string passing paths at an angle less than 90 degrees. The tensile force imparted to the strings can be varied by varying the angle of incline.
Next, the present invention is directed to a tailpiece used in the string locking structure for an electric guitar described above, characterized in comprising:
a tailpiece main body member;
a plurality of first string passing paths for locking the strings, the first string passing paths extending through the tailpiece main body member and being parallel to each other; and
a plurality of second string passing paths for locking the strings, the first string passing paths extending through the tailpiece main body member and being parallel to each other; and
when the tailpiece main body member has been attached to the front surface of the body of the electric guitar, the first string passing paths extending linearly from first front-end openings exposed in the front surface portion facing toward the head of the electric guitar within the tailpiece main body member up to first rear-end openings exposed in the rear surface portion facing the opposite direction from the front surface portion, and the second string passing paths extending at a curve from second front-end openings exposed in the front surface portion up to second rear-send openings exposed in the bottom surface portion in contact with the front surface of the body.
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An embodiment of an electric guitar to which the present invention is applied is described below with reference to the drawings. The basic configuration of a Les-Paul-type electric guitar 1 of the present invention is a common configuration having a body 2, a neck 3, and a head 4, and two pickups 6, 7, a bridge 8, and a tailpiece 9 are attached to a front surface 5 of the body 2 from the neck side, as shown in
Specifically, the tailpiece attachment bolts 15, 16 are threaded through and fixed to nuts (not shown) embedded in advance in the body 2, and heads 15a, 16a of the bolts protrude from the front surface 5 of the body 2. Discoid flanges 15b, 16b are formed in positions at fixed gaps from the heads 15a, 16a, and the top surfaces of the flanges 15b, 16b are positioned at the same height as the front surface 5 of the body 2. The portions of the tailpiece 9 where the left and right bolt-fitting grooves 13, 14 are formed are inserted from the rear of the tailpiece attachment bolts 15, 16, in between the heads 15a, 16a and the flanges 15b, 16b.
Formed in the tailpiece main body member 12 are six first string passing paths 17 for locking strings that extend through the main body member and that are parallel to each other, and six second string passing paths 18 for locking strings that extend through the tailpiece main body member 12 that are parallel to each other. The string passing paths 17 are linear passing paths that lead from first front-end openings 17a exposed in a front surface portion 19 facing toward the head 4 of the electric guitar 1 in the tailpiece main body member 12, to first rear-end openings 17d exposed in a rear surface portion 20 facing the opposite direction of the front surface portion 19. The second string passing paths 18 are courses that lead from second front-end openings 18a exposed in the front surface portion 19 of the tailpiece main body member 12, to second rear-end openings 18d exposed in a bottom surface portion 21 in contact with the front surface 5 of the body 2 in the tailpiece main body member 12.
Each of the first string passing paths 17 comprises a first front-side string passing path portion 17b on the side of the first front-end opening 17a, and a first rear-side string passing path portion 17c on the side of the first rear-end opening 17d. Each of the second string passing paths 18 comprises a second front-side string passing path portion 18b on the side of the front-end opening 18a, and a second rear-side string passing path portion 18c on the side of the second rear-end opening 18d. In the present example, the first front-side string passing path portion 17b and the second front-side string passing path portion 18b constitute a shared front-side string passing path portion 22, and the first front-end opening 17a and second front-end opening 18a at the front ends thereof constitute a shared front-end opening 23. The first rear-side string passing path portion 17c of the first string passing path 17 is a linear continuation of the rear end of the front-side string passing path portion 22, but the second rear-side string passing path portion 18c of the second string passing path 18 extends linearly in a direction bent at a right angle from the rear end portion of the front-side string passing path portion 22.
A body-side string passing hole 24 is formed passing through the body 2 in the thickness direction. The body-side string passing hole 24 is a through-hole leading from a front surface opening 24a exposed in the front surface 5 of the body 2 to a rear surface opening 24b exposed in the rear surface 25 of the body 2. The front surface openings 24a of the body-side string passing holes 24 all communicate with respective second rear-end openings 18d of the second string passing paths 18 of the tailpiece main body member 12 attached to the front surface 5 of the body 2.
In the string locking structure of this configuration, the strings 10 can be passed through the first string passing paths 17 from the rear side of the tailpiece main body member 12, and locked in a first string locked state in which the ball ends 10a at the rear ends of the strings are locked in the first rear-end openings 17d of the first string passing paths 17, as shown by the imaginary line A in
a) to (e) are, respectively, a front view, a plan view, a rear view, a right-side view, and a bottom view, all showing the tailpiece 9; and
As previously described, each first string passing path 17 is a through-path extending linearly and comprises a front-side string passing path portion 22 (a first front-side string passing path portion 17b) and a first rear-side string passing path portion 17c, the front end of the front-side string passing path portion 22 being joined to the front-end opening 23 (the first front-end opening 17a) of the front surface portion 19 of the tailpiece main body member 12, and the rear end of the first rear-side string passing path portion 17c being joined to the first rear-end opening 17d of the rear surface portion 20. The front-side string passing path portion 22 of the present example is a groove of fixed width opening in a top surface portion 26 of the tailpiece main body member 12, a groove bottom surface 22a thereof being defined by a semicircular curved surface, and left and right groove side surfaces 22b being defined by flat side surfaces extending perpendicular to the bottom surface portion 21 from the side edges of the groove bottom surface toward the top surface portion 26.
The first rear-side string passing path portion 17c is composed of a small-diameter hole portion 17e having the same curvature radius as the groove bottom surface 22a, a tapered hole portion 17f expanding as a continuation of the rear end thereof, and a large-diameter hole portion 17g continuing from the rear end thereof, the rear end of the large-diameter hole portion 17g being joined to the first rear-end opening 17d. The groove-shaped front-side string passing path portion 22 and the small-diameter hole portion 17e of the first rear-side string passing path portion 17c are larger than the outside diameter of the string 10 and smaller in diameter than the ball end 10a, and the ball end 10a of the string 10 can be inserted through the large-diameter hole portion 17g in the rear side.
The front-side portion of the second string passing path 18 constitutes the shared front-side string passing path portion 22 with the first string passing path 17, and the rear-side portion constitutes the second rear-side string passing path portion 18c bent at a right angle from the rear-end portion of the front-side string passing path portion 22 toward the bottom surface portion 21 and then extending linearly. The rear end of the second rear-side string passing path portion 18c is joined to the second rear-end opening 18d exposed in the bottom surface portion 21. The second rear-side string passing path portion 18c is composed of a small-diameter hole portion 18e having the same radius as the curvature radius of the groove bottom surface 22a, a tapered hole portion 18f expanding as a continuation of the rear end thereof, and a large-diameter hole portion 18g continuing from the rear end thereof, the rear end of the large-diameter hole portion 18g being joined to the second rear-end opening 18d. The small-diameter hole portion 18e of the second rear-side string passing path portion 18c is larger than the outside diameter of the string 10 and smaller in diameter than the ball end 10a, and the ball end 10a of the string 10 can be inserted through the large-diameter hole portion 18g in the rear side.
The small-diameter hole portion 18e of the second rear-side string passing path portion 18c opens in the rear end of the groove bottom surface 22a of the groove-shaped front-side string passing path portion 22. Between the rear end portion of the groove bottom surface 22a and the internal peripheral surface portion of the small-diameter hole portion 18e is a curved portion 27 where these two portions continue smoothly due to a convex curved surface, as can be seen in
In the tailpiece 9 of this configuration, the front half portions of the first string passing path 17 and the second string passing path 18 constitute the shared groove-shaped front-side string passing path portion 22. Therefore, after the string 10 is pulled out from the rear surface 25 of the body 2 through the second string passing path 18 to the top surface portion 26 of the tailpiece 9, the operation of pulling the string 10 out forward along the shared front-side string passing path portion 22 can easily be performed.
a) to (c) are explanatory drawings showing modifications of the tailpiece 9 comprising the first string passing path 17 and the second string passing path 18. In the tailpiece 9A shown in
In the tailpiece 9B shown in
The tailpiece 9C shown in
In the above examples, a rear-side string passing path portion of the second string passing path and a third string passing hole formed in the body extend in the thickness direction of the body, but these portions can also be formed so as to extend in a direction inclined relative to the thickness direction of the body. For example, these portions can be inclined at acute angles forward and backward relative to the thickness direction of the body, as indicated by the arrows C and D shown by the single-dash lines in
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/004888 | 8/31/2011 | WO | 00 | 2/25/2014 |