JP5672841B2 - Stringed instrument - Google Patents

Description

  The present invention relates to a stringed instrument such as a guitar.

  Conventionally, stringed instruments such as guitars are stringed only on one side as described in Patent Document 1. As a result, a bending moment in one direction due to the tension of the string is always applied to the member (for example, the neck of the guitar) on which the string is stretched.

JP 2004-361975 A

  For this reason, conventionally, in order to suppress bending deformation of the member due to this bending moment (for example, warping of the neck of the guitar), it is necessary to give the member a large bending rigidity, which makes the whole stringed instrument heavy and increases the cost. However, there are problems such as inevitable and less freedom of material selection. Further, even if the member has a large bending rigidity, the member may bend and deform due to aging deterioration or the like, and the performance may be deteriorated.

Therefore, the inventor has proposed a stringed instrument comprising a base member having strings on both sides, for example, in Japanese Patent Application No. 2010-168471. However, in a configuration in which strings are stretched simply on both sides, the vibration generated by playing a string on one side is transmitted to the string on the other side, and the string on the other side has a natural frequency corresponding to its fixed length. Will resonate. In the case of a song that does not use the vibration sound of the string on the other side as a constituent sound, the vibration sound of the string on the other surface side becomes incoherent and the performance is lowered.
The problem to be solved by the present invention is to provide a stringed instrument in which strings are stretched on both sides, and a stringed instrument in which performance deterioration due to unnecessary string vibration as described above is prevented is provided.

In order to solve the above problems, the present invention includes the following components.
The invention according to claim 1 is a base member in which strings are stretched vertically,
A musical instrument case to which the base member is attached;
A string vibration control member that is detachably attached to the instrument case and changes the vibration of the string , and
The string vibration control member is a stringed instrument having a knot forming portion that contacts the string and forms a knot of vibration in the string .

  The invention according to claim 2 is characterized in that the string is continuously stretched from the upper side to the lower side of the base member by being folded back at one end of the base member. The stringed instrument according to Item 1.

According to a third aspect of the present invention, the musical instrument case is attached to the base member in a state where the string located on the upper side of the base member is exposed.
The stringed musical instrument according to claim 1, wherein the string vibration control member acts on the string located below the base member.

The invention according to claim 4 is characterized in that the string vibration control member has a vibration absorbing portion that contacts the string and absorbs vibration of the string. A stringed instrument according to any one of the above .

In the invention according to claim 5 , a plurality of the strings are stretched in parallel,
The stringed musical instrument according to any one of claims 1 to 4 , wherein the string vibration control member acts on a specific string among the plurality of strings.

  According to the present invention, the string vibration control member is attached to the instrument case to change the vibration of the string. For this reason, by attaching this string vibration control member to the instrument case, for example, unnecessary string vibration can be eliminated or it can be changed to a vibration useful for performance. Further, since the string vibration control member can be attached to and detached from the musical instrument case, the string vibration control member can be attached and detached to appropriately change the vibration of the string according to the performance needs. Accordingly, it is possible to prevent performance deterioration due to unnecessary string vibration, and in some cases, it is possible to improve performance quality by adding sounds useful for performance.

It is the top view which showed 1st Embodiment (electric guitar) of the stringed musical instrument to which this invention is applied. It is a sectional side view in the AA arrow of the stringed musical instrument shown by FIG. (A) is sectional drawing in the BB arrow view of the stringed musical instrument shown in FIG. 2, (b) is sectional drawing in CC arrow of the stringed musical instrument shown in FIG. It is the top view which showed the string module of the stringed musical instrument shown in FIG. It is the sectional side view which showed the string module of the stringed instrument shown by FIG. It is an expansion perspective view which shows the string tension adjusting device of the stringed musical instrument shown in FIG. (A) is sectional drawing in the DD arrow view of the stringed musical instrument shown in FIG. 2, (b) is the same sectional drawing as (a), and is a figure which shows the state which removed the string vibration control member. . It is a perspective view which shows the state which removed the string vibration control member from the musical instrument case. (A) is sectional drawing which shows the state which attached the string vibration control member which is another embodiment to the musical instrument case, (b) is sectional drawing which shows the state which removed the string vibration control member, (c ) Is a cross-sectional view taken along line EE of (a). It is a fragmentary sectional side view of the string module which is other embodiment of this invention. It is a sectional side view of the string module which is other embodiment of this invention.

Hereinafter, a first embodiment of a stringed musical instrument to which the present invention is applied will be described with reference to FIGS.
As shown in FIGS. 1 and 2, the stringed instrument of the present embodiment includes a string module 1 in which six strings S1 to S6 having different sound ranges are stretched, a musical instrument case 2 to which the string module 1 is detachably attached, An electric guitar (a bodyless type) including an electromagnetic pickup 3 and a string vibration control member 80 that is detachably attached to the musical instrument case 2. The strings S1 to S6 are simply expressed as strings S if they are not distinguished from each other.

  The electromagnetic pickup 3 is disposed on the upper surface of the musical instrument case 2 and a base member 10 described later below each string S, and is fixed to the musical instrument case 2 with mounting screws 4. The electromagnetic pickup 3 is disposed on a metal yoke 5 disposed at a position corresponding to each string S, a coil 6 (shown in FIG. 2) wound around the yoke 5, and a lower side of the yoke 5. And a permanent magnet (not shown) that converts the vibration of each string S into an electrical signal. The converted electrical signal is output to, for example, an external amplifier with a speaker through a cable 8 connected to the terminal 7 of the electromagnetic pickup 3, thereby producing a sound corresponding to the performance of the guitar.

As shown in FIGS. 4 and 5, the string module 1 includes a base member 10, strings S (strings S <b> 1 to S <b> 6), and a string tension adjusting device 11 provided for each string S.
The base member 10 is a strip-like member as a whole, and in the case of this example, is made of a metal (for example, stainless steel) or ceramic with high wear resistance. As shown in FIG. 5, when the base member 10 is arranged so that the longitudinal direction is the left and right direction and the surface on which the string is stretched is the upper and lower surfaces, the string support portions are vertically arranged at both ends in the left and right direction. Protruding at the same height, strings can be stretched on both the upper surface side and the lower surface side, and the upper and lower surfaces can be reversed and replaced with the instrument case 2. Further, in this example, each string S is folded at one end portion (left end portion in FIG. 5) of the base member 10, so that each string S is continuously stretched on the upper and lower surfaces of the base member 10.

  In this case, as the string support portion, nuts 12 and 13 are provided at the left end portion of the base member 10 so as to protrude vertically at the same height, and the bridges 14 and 15 are provided at the same height vertically at the right end portion of the base member 10. Protrusively provided. These string support portions (nuts 12 and 13 and bridges 14 and 15) support the strings S by contacting the back sides of the strings S, and their upper end surfaces (or lower end surfaces) are simply flat. However, a groove into which each string S fits may be formed. If there is this groove, the displacement of each string S (the displacement in the front-rear direction perpendicular to the plane of FIG. 2) is prevented. Further, the protruding height of the nuts 12 and 13 (string height to be described later) and the protruding height of the bridges 14 and 15 may be different.

  Here, the fact that the string support portions are provided so as to protrude vertically at the same height means that the string height of each string S in the string support portion (the distance from the surface of the base member to the center of the string) is the base member 10. It means that the upper surface side and the lower surface side are equal. In other words, in the side sectional view of the base member 10 as shown in FIG. 5, the distance from the center line M of the base member 10 along the longitudinal direction of the base member 10 (left-right direction in FIG. 5) to the center of the upper and lower strings S. Means that they are equal to each other. Here, the center line M in the side sectional view of the base member 10 is a line corresponding to a neutral plane (a plane in which stress due to bending of the beam becomes zero) when the base member 10 is considered as a beam. is there. In this example, as shown in FIG. 5, the overall shape of the base member 10 is a vertically symmetrical shape with this neutral plane as a boundary.

  With such a configuration of the base member 10, if the tension of the string S is equal in the vertical direction (in this example, the string S is continuous in the vertical direction and the tension is equal), the string S tension causes the string support portion of the base member 10 to move. The applied bending moment cancels out vertically and becomes zero. Needless to say, even if the protruding heights of the string support portions are equal, there may be a slight difference that is allowed within the target quality range. Even if there is a slight difference, the bending moment is remarkably small and almost zero compared to the conventional configuration in which a string is stretched only on one side.

  4 and 5, the nut side between the bridge and the nut on the upper surface and the lower surface of the base member 10 constitutes finger plate portions (finger boards) 16 and 17, and The side of the bridge between the nuts constitutes performance parts 18 and 19. The fingerboard portions 16 and 17 are places where the player presses the string S with his / her fingers, and the frets 21 and 22 are formed at intervals that realize a predetermined scale (for example, a chromatic scale). Here, the frets 21 and 22 are elongated protruding portions formed on the upper surface or the lower surface of the base member 10, and extend uniformly in the cross-section in the front-rear direction (the width direction of the base member 10) perpendicular to the paper surface of FIG. 5. As shown in FIG. 5, the cross-sectional shape is a shape that protrudes up and down in a mountain shape. Further, the frets 21 and 22 of this example are formed integrally with the base member 10. Such a fret is a well-known fret that hits the back side of the string S when the performer presses the string S and changes the pitch due to the vibration of the string S in a predetermined scale. There can also be a configuration. Next, the performance units 18 and 19 are places where the player plays the string S with fingers or picks, and the electromagnetic pickup 3 described above is attached to these performance units 18 or 19.

  As shown in FIGS. 4 and 5, an adjustment device support portion 23 is provided at the right end portion of the base member 10 so as to extend further to the right from the position of the bridge 14. In this example, the adjustment device support portion 23 is formed integrally with the base member 10. The adjustment device support portion 23 has a frame-like shape having an opening portion 23a that opens in a rectangular shape up and down on the inner side and a band plate-like portion 23b on the right end. The adjusting device support portion 23 is also formed vertically symmetrically about the center line M (neutral surface), and the longitudinal direction of the band plate-like portion 23b is perpendicular to the width direction of the base member 10 (the paper surface of FIG. 5). Direction). Further, in the band plate-like portion 23b of the adjusting device support portion 23, there are as many through holes 24 (shown in FIGS. 5 and 6) penetrating in the longitudinal direction of the base member 10 as the number corresponding to the number of strings S. The members 10 are formed side by side in the width direction. The positions of the through holes 24 in the width direction correspond to the positions of the strings S, respectively, and are also located on the center line M in the side sectional view of FIG.

  As shown in FIG. 4, at the center position in the width direction of the base member 10, screw holes 25 for fixing the base member 10 to the musical instrument case 2 are provided at a plurality of locations in the longitudinal direction of the base member 10 (in this case, 5 ). In this example, the screw hole 25 is formed so as to penetrate vertically. The mode of the screw hole 25 (arrangement, whether or not it penetrates up and down, etc.) may be any mode as long as the upper and lower surfaces of the base member 10 can be reversed and replaced with the instrument case 2. .

  Further, as shown in FIG. 5, a nut fixing washer 26 is fixed to the left end of the base member 10 by two nut fixing screws 27 in this case. The nut fixing washer 26 is a strip-like member that is disposed horizontally along the width direction of the base member 10 (the front-rear direction perpendicular to the paper surface of FIG. 5). The nut fixing screw 27 is inserted into through holes (not shown) formed at both front and rear ends of the nut fixing washer 26 and is formed at a position where it does not interfere with each string S on the left end surface of the base member 10. The nut fixing washer 26 is fixed so as to be pressed against the left end surface of the base member 10 by being screwed into a screw hole (not shown). In addition, many fine grooves are formed on the entire outer peripheral surface of the nut fixing screw 27 so as not to slip when the user rotates it with a finger.

  The folded portion of each string S is sandwiched between the nut fixing washer 26 and the left end surface of the base member 10 (in this case, the left end surfaces of the nuts 12 and 13). As a result, the movement (slip) of each string S at the folded portion during performance is restricted. Note that a member such as the nut fixing washer 26 is not essential, and may be appropriately provided according to the necessity of regulating the movement of each string S at the folded portion.

  Next, in each case, each string S (S1 to S6) has a string main body made of a metal wire so that the electromagnetic pickup 3 functions. As shown in FIGS. 5 and 6, a pole end SE larger than the thickness of the string body is provided at one end of each string S. Each string S is folded by a string support portion (nuts 12 and 13) located at one end portion (left end portion) of the base member 10, so that the other end portion (right end portion) of the base member 10 is moved to the one end portion. Further, the base member 10 is continuously stretched over the upper and lower surfaces of the base member 10 from the one end to the other end. Since each string S is continuous on the upper and lower surfaces, between the upper ends of the string support portions of the base member 10 (that is, between the nut 12 and the upper end portions of the bridges 14 in FIG. 5) and between the lower ends of the string support portions. In other words, in the case of FIG. 5, the tension is stretched between the nut 13 and the lower end of the bridge 15 with the same tension.

Next, as shown in FIGS. 4, 5 and 6, the string tension adjusting device 11 includes a string tension adjusting member 33, an adjusting screw shaft 34, an adjusting nut 35, and a lock nut 36, and each string S One set is provided for each of the above. As shown in FIG. 4, the string tension adjusting device 11 of each string S is provided side by side in the width direction of the base member 10 corresponding to the arrangement of each string S.
Here, as shown in FIG. 6, the string tension adjusting member 33 is a rectangular parallelepiped member as a whole, and is disposed in the opening 23a of the adjusting device support 23 described above, and both ends of the string S are fixed. It is a member.

  As shown in FIG. 6, on the relatively left side of the string tension adjusting member 33, a pole end holding recess 37 into which the pole end SE of the string S can be inserted from the upper surface is formed on the upper surface. Further, a string insertion hole 38 communicating with the pole end holding recess 37 is formed from the left end surface of the string tension adjusting member 33. The string insertion hole 38 is a through hole that is inclined downward toward the left, and is a hole for pulling out the string S from the pole end holding recess 37 toward the lower end of the string support portion (the lower end of the bridge 15 in FIG. 5). The inner diameter is smaller than the outer shape of the pole end SE. A string fixing recess 40 for fixing the other end of the string S with the string fixing screw 39 is formed on the relatively right side of the string tension adjusting member 33 in an open state on the upper surface. A screw hole (not shown) for screwing the shaft of the string fixing screw 39 is formed on the bottom surface of the string fixing recess 40. The other end of the string S is fixed to the string tension adjusting member 33 by being sandwiched between the bottom surface of the string fixing recess 40 and the head of the string fixing screw 39 screwed into the screw hole. The

  As shown in FIG. 5, the adjustment screw shaft 34 is provided so as to extend from the right end surface of the string tension adjustment member 33 on the extension of the center line M, and in the band plate-like portion 23 b of the adjustment device support portion 23. A screw shaft that is slidably inserted into the through hole 24 and is provided integrally with the string tension adjusting member 33. The tip end portion (right end portion in FIG. 5) of the adjustment screw shaft 34 penetrates the through hole 24 and protrudes outward (right side) from the strip plate portion 23b.

  As shown in FIG. 6, both the adjustment nut 35 and the lock nut 36 are nuts that are screwed onto the outer periphery of the adjustment screw shaft 34. The outer diameters of the adjustment nut 35 and the lock nut 36 are through holes 24. Naturally, it is larger than the inner diameter. Among these, the lock nut 36 is disposed on the inner side (left side) of the band plate-like portion 23 b by being screwed in advance to the base end side of the adjustment screw shaft 34. On the other hand, after the adjustment screw shaft 34 is inserted into the through hole 24 of the strip plate portion 23b, the adjustment nut 35 protrudes outward (right side) from the strip plate portion 23b of the adjustment screw shaft 34. Screwed into the part. In addition, many fine grooves are formed on the entire outer peripheral surface of the adjustment nut 35 and the lock nut 36 so as not to slip when the user rotates with a finger.

  Here, the string tension adjusting member 33 of each string tension adjusting device 11 is disposed adjacent to the opening 23a with a slight gap as shown in FIG. It is considered impossible to rotate around. However, each string tension adjusting member 33 has the other ends (the bridges 14 and 15 are provided) along the center line M (straight line m in FIG. 6) so that adjacent side surfaces slide. It is possible to move in a direction approaching / separating (position in FIG. 5). 6 is a straight line in the neutral plane of the base member 10 described above, and is a straight line parallel to the longitudinal direction of the base member 10 (left-right direction in FIG. 5). That is, the straight line m is a line corresponding to the center line M in FIG. The straight line m passes through the centers of the adjusting screw shaft 34 and the through-hole 24 and passes through fixed positions (or the vicinity thereof) at both ends of the string S in the string tension adjusting member 33.

  In the string tension adjusting device 11 configured as described above, each string S can be stretched and held in the tensioned state as follows, and tuning (tuning) for adjusting the tension of each string S is performed. Is easily possible. That is, first, the other end of the string S is inserted from the pole end holding recess 37 of the string tension adjusting member 33 and pulled out from the string insertion hole 38, and the lower surface side of the base member 10 is set to one end (left end) of the base member 10. After the other end side of the string S is pulled and drawn around, the string S is folded upward at one end of the base member 10 (in this case, the positions of the nuts 12 and 13). Next, the upper surface side of the base member 10 is directed toward the other end portion (right end portion) of the base member 10, the other end side of the string S is pulled, and the pole end SE at one end portion of the string S fits into the pole end holding recess 37. And hold it. Thereafter, the other end side of the string S is wound around the shaft of the string fixing screw 39 while being pulled to some extent, and the string fixing screw 39 is fixed to the bottom portion in the string fixing recess 40 of the string tension adjusting member 33. Thereby, the string S is continuously stretched on the upper and lower surfaces of the base member 10. In addition, when the groove | channel mentioned above is formed in the front end surface of the nuts 12 and 13 and the bridge | bridgings 14 and 15, the string S should just be stretched as mentioned above, inserting the string S in this groove | channel. Further, the nut fixing screw 27 and the nut fixing washer 26 may be removed once when the strings S are stretched and attached after the strings S are stretched.

  Then, after the string S is stretched as described above, the lock nut 36 is rotated and loosened in a direction away from the band plate-like portion 23b, and then the adjustment nut 35 is rotated in a direction to press against the band plate-like portion 23b. When tightened, the adjusting screw shaft 34 and the string tension adjusting member 33 move in the direction away from the other end of the base member 10 (the right side in FIG. 5), whereby the string S is further pulled to increase the tension. . Or, conversely, when the adjustment nut 35 is rotated and loosened in a direction away from the band plate portion 23b, the adjustment screw shaft 34 and the string tension adjustment member 33 approach the other end of the base member 10 (left side in FIG. 5). ), Thereby reducing the tension of the string S. Then, after the adjustment nut 35 is rotated, if the lock nut 36 is rotated and tightened in such a direction as to be pressed against the strip plate portion 23b, the adjustment nut 35 and the lock nut 36 sandwich the strip plate portion 23b. Since the tightening is performed, the adjusting screw shaft 34 and the string tension adjusting member 33 are fixed to the base member 10 so as not to move, and the string S is held in a tensioned state with a predetermined tension.

Therefore, by performing the above-described operation for each string S, even a general user can easily tune each string S, hold it in a stretched state, and adjust the tension of each string S. is there.
Here, in a state where both ends of the string S are fixed to the string tension adjusting member 33 as described above, the position of the pole end SE that is a fixed position on one end side of the string S and the fixed position on the other end side of the string S are determined. As described above, the position of the bottom surface of a certain string fixing recess 40 is, in other words, the extension of the neutral surface of the base member 10 described above. In other words, the center line M of the base member 10 described above in the side sectional view shown in FIG. It is arranged on the extension. That is, both end portions of the string S are separated from the other end portion of the base member 10 on the extension of the center line M of the base member 10 along the direction from one end portion to the other end portion of the base member 10 (in FIG. 5). , To the right).

  In the above-described string tension adjusting device 11, the adjusting nut 35 is rotated by inserting, for example, a nylon washer between the adjusting nut 35 and the band plate-like portion 23 b on the outer periphery of the adjusting screw shaft 34. May be made smoother. Alternatively, the adjusting nut 35 can be rotated by interposing a member for improving slippage between the inner periphery of the above-described through hole 24 of the band plate-like portion 23b and the outer periphery of the adjusting screw shaft 34 inserted therethrough. The sliding of the adjustment screw shaft 34 accompanying the above may be made smoother.

Next, the bending moment applied to the base member 10 by the tension of the string S of the string module 1 of this example will be described.
The string module 1 includes a base member 10 provided with string support portions (nuts 12 and 13 and bridges 14 and 15) protruding at the same height at both ends, and the string support portion of the base member 10. And a string S stretched between the upper end portions and between the lower end portions of the string support portions with the same tension. For this reason, the bending moment which generate | occur | produces in the base member 10 by the tension | tensile_strength added to the said string support part at least by the string S stretched between the said string support parts cancels up and down, and becomes zero.

  Further, the string module 1 of the present example includes a base member 10 provided with string support portions protruding at the same height at both ends, and a string support portion (nut 12) positioned at one end portion of the base member 10. 13), the string S continuously stretched over the base member 10 from the other end of the base member 10 to one end, and from one end of the base member 10 to the other end. Both ends of the string S are extended from the other ends (bridges 14 and 15) of the base member 10 on the extension of the center line M of the base member 10 along the direction from one end to the other end of the base member 10. Has been pulled away. That is, a continuous string S having the same tension is stretched symmetrically at the same height on both the upper and lower sides of the center line M of the base member 10, and both ends of the string S are extended to the base line M on the base line M. It is pulled in a direction away from the other end of the member 10. For this reason, the bending moment which generate | occur | produces in the base member 10 with the tension | tensile_strength of the whole string S cancels up and down, and becomes zero.

  Next, as shown in FIGS. 1 and 2, the musical instrument case 2 is a box-shaped member having an open upper surface as a whole, and is manufactured by, for example, synthetic resin integral molding. As shown in FIG. 1, the instrument case 2 has dimensions in the front-rear direction and the left-right direction inside that are substantially the same as the outer dimensions in the front-rear direction and the left-right direction of the string module 1 including the base member 10. The string module 1 is attached in a state where the string module 1 is fitted inside with a slight gap in a state where each string S located on the upper side is exposed on the upper surface side. Further, a boss 29 protruding upward is formed at a position corresponding to the screw hole 25 of the base member 10 on the bottom surface of the musical instrument case 2. When the string module 1 is attached, the upper end surface of the boss 29 is It contacts the lower surface of the base member 10. As shown in FIG. 2, the boss 29 is hollow inside, and this hollow portion opens to the lower surface side of the musical instrument case 2, and the upper end portion of the boss 29 is vertically connected to insert the mounting screw 30. A through-hole (not shown) penetrating through the screw hole 25 is formed at a position coaxial with the screw hole 25.

  Then, the base member 10 is inserted into the instrument case 2 by inserting the attachment screw 30 into the boss 29 from the lower surface side of the instrument case 2, passing through the through hole at the upper end of the boss 29, and screwing into the screw hole 25. The string module 1 is fixed and attached to the musical instrument case 2. 2 and 3, when the string module 1 is attached to the instrument case 2, the bottom wall of the instrument case 2 covers the lower surface of the string module 1, and the side wall of the instrument case 2 is the side portion of the string module 1. Cover the outer periphery. However, as shown in FIG. 2, the upper end side of the right end wall of the musical instrument case 2 is formed with a concave portion 31 into which the band plate-like portion 23 b of the adjusting device support portion 23 is fitted, and through this concave portion 31, The band plate portion 23b is exposed to the right side. As a result, the aforementioned adjustment nut 35 is also exposed to the right side, so that the operation of operating the aforementioned adjustment nut 35 for tuning can be easily performed with the string module 1 attached to the instrument case 2.

When the string module 1 is attached to the instrument case 2 as described above, the guitar neck is formed by the instrument case 2 and the base member 10 of the string module 1 as shown in FIGS. The interior of the neck is hollow, which is advantageous for weight reduction.
As shown in FIG. 2, strap pins 32 for attaching a strap to be worn by the performer on the shoulder are provided on the left end surface and the right end surface of the musical instrument case 2 so as to protrude from the end surfaces.

  Further, as shown in FIGS. 7B and 8, the bottom wall of the musical instrument case 2 has an opening that partially exposes each string S on the back side (the lower side in FIG. 7B) of the base member 10. 41 is formed. The opening 41 is formed so as to cross the bottom of the instrument case 2 from the front side to the side in the width direction of the instrument case 2 (the front-rear direction orthogonal to the paper surface of FIG. 2). The 80 substrate portions 81 are sized to fit into a slight gap. At the front and rear end positions of the opening 41, mounting recesses 42 into which mounting pieces 83 to be described later of the string vibration control member 80 are fitted are formed, respectively. Engagement projections 43 projecting rearward are formed.

  Note that the position of the opening 41 in the longitudinal direction (left and right direction in FIG. 2) of the instrument case 2 and each string S is a predetermined position for attaching the string vibration control member. This predetermined position is a preferable position for attaching the string vibration control member. For example, when it is assumed that only a string vibration control member of a type that absorbs vibration of all strings S (so-called mute) such as the string vibration control member 80 shown in FIG. Can be absorbed, and is not particularly limited as long as no interference of members occurs. However, when it is assumed that a string vibration control member of a type that forms a vibration node in any of the strings S, such as a string vibration control member 90 shown in FIG. This opening is a position corresponding to a position where a node is to be formed in the direction (hereinafter referred to as a node forming position), and when the string vibration control member is attached, the opening is formed so that the node is accurately formed at this node forming position. 41 must be set in the longitudinal direction.

  Next, as shown in FIGS. 7A and 7B and FIG. 8, the string vibration control member 80 includes a substrate portion 81 and a vibration absorption portion 82 provided inside the substrate portion 81. Here, the board part 81 is made of the same material (for example, made of synthetic resin) as the musical instrument case 2, for example, and is mounted so as to close the opening 41 described above and integrated with the musical instrument case 2 without a step. It is said that. At both ends of the substrate portion 81, attachment pieces 83 that are elastically bent when the string vibration control member 80 is attached and fit into the attachment recesses 42 are formed. The attachment pieces 83 are respectively formed with engagement recesses 84 into which the above-described engagement protrusions 43 are fitted when the string vibration control member 80 is attached. With such a configuration, the string vibration control member 80 can be easily attached with one touch by being pushed into the opening 41 of the musical instrument case 2, and conversely by being pulled out from the opening 41, the user can remove the string vibration control member 80. It can be easily removed.

  Note that the attachment pieces 83 at both ends of the board portion 81 are once bent flexibly outward so as to get over the engagement protrusions 43 when the string vibration control member 80 is attached to the opening 41, and then the attachment pieces 83 In this case, the engaging protrusion 43 is engaged with and engaged with the engaging recess 84 of the mounting piece 83. Therefore, when the string vibration control member 80 is pulled out from the opening 41 and removed, at least one of the attachment pieces 83 at both ends of the board portion 81 is once bent outward and the attachment projection 43 is attached to the attachment portion 83. It is necessary to remove the engagement recess 84 of the piece 83. Therefore, for example, a concave portion for hooking a finger to make such an operation (an operation of pulling out the substrate portion 81 while bending the mounting piece 83 of the substrate portion 81 outward) can be performed. You may form in an outer surface etc.

  The vibration absorbing portion 82 is made of a mute material such as silicon rubber (a material capable of absorbing the vibration of the string by contacting the string). For example, the substrate portion 81 (a portion excluding the attachment piece 83 and the vicinity thereof) by bonding. It is fixed to the inner surface. When the string vibration control member 80 is attached to the opening 41 of the musical instrument case 2, the vibration absorbing portion 82 is attached to each string S on the back side (lower side in FIG. 7) of the base member 10 as shown in FIG. As shown in FIG. 2, the surface is sufficiently in contact with each other, and the size of each string S can be sufficiently prevented. The vibration absorbing portion 82 is not limited to rubber, and may be, for example, a flexible sponge-like synthetic resin (urethane sponge or the like).

Next, the case where this guitar is assembled will be described.
The string module 1 is assembled by attaching each string tension adjusting device 11 to the base member 10 and then stretching each string S as described above using each string tension adjusting device 11. Then, the string module 1 is fitted into the musical instrument case 2 with either the upper or lower surface of the string module 1 exposed upward, and then the mounting screw 30 is inserted into the boss 29 from the lower surface side of the musical instrument case 2. The base member 10 is fixed to the instrument case 2 by being inserted into the through hole at the upper end of the boss 29 and screwed into the screw hole 25 of the base member 10, and the string module 1 is fixed to the instrument case 2. Can be attached. When the electromagnetic pickup 3 and the string vibration control member 80 are attached to the musical instrument case 2, the assembly of the guitar is completed. The electromagnetic pickup 3 may be disposed at a predetermined position on the upper surface of the base member 10 or the musical instrument case 2 below each string S and fixed to the musical instrument case 2 with the mounting screws 4 described above. Further, the string vibration control member 80 can be easily attached by being pushed into the opening 41 of the musical instrument case 2 as described above.

  In addition, if the above assembly procedure or the reverse procedure is performed, this guitar can be easily assembled or disassembled by a general user, and the upper and lower surfaces (front and back) of the string module 1 can be easily reversed. The string vibration control member 80 can be easily attached and detached. That is, the electromagnetic pickup 3 is temporarily removed, the string module 1 is removed and the upper and lower surfaces are inverted, and then the instrument module 2 is attached again, and then the electromagnetic pickup 3 is attached. be able to. The string vibration control member 80 can be easily removed by pulling it out from the opening 41 as described above. In this guitar, the attachment / detachment of the string module 1 and the attachment / detachment of the string vibration control member 80 can be performed independently of each other. Therefore, when assembling the guitar, the string vibration control member 80 can be attached to the instrument case 2 in advance, and the string module 1 can be attached and detached while the string vibration control member 80 is attached to the instrument case 2. Of course it is also possible to do.

  According to the stringed musical instrument (this guitar) of the first embodiment described above, the string vibration control member 80 is attached to the musical instrument case 2 to change the vibration of the string. In this example, as shown in FIG. 7A, the vibration absorbing portion 82 of the string vibration control member 80 contacts each string S to absorb the vibration of each string S on the back side (so-called mute each string S). . For this reason, by attaching the string vibration control member 80 to the musical instrument case, it is possible to eliminate the sound caused by the vibration of each string S on the back side (vibration of the open string on the back side) unnecessary for performance. Since the string vibration control member 80 can be attached to and detached from the musical instrument case 2, the string vibration control member 80 is removed according to performance needs, and the vibration of each string S on the back side is actively used. The performance quality can be improved by adding sounds useful for performance. For example, when playing a song in which the sound of the open string of each string S matches the tonality, it is preferable to remove the string vibration control member 80 and actively use the vibration of each string S on the back side. Often results are obtained. The guitar has a string (resonant string) for resonating by vibration of the basic string in addition to a string (basic string) for playing by playing with a finger (referred to as a sitar or sitar guitar). Stuff). If the string vibration control member 80 is removed in the guitar of this example and the strings on the back side are opened, each string S on the back side functions as a resonance string of the sitar guitar. That is, this guitar can produce a sound similar to a sitar guitar by removing the string vibration control member 80.

  When the string vibration control member 80 is removed, the opening 41 of the musical instrument case 2 is opened and the strings S on the back side are exposed. However, the lid member of the opening 41 (for example, string vibration control) When the string vibration control member 80 is removed when the string vibration control member 80 is removed separately from the member 80, the opening portion 41 is replaced with the lid 41. It is possible to close the opening 41 by attaching it.

  In addition, even if the string tension is excessively adjusted, this guitar does not generate a bending moment due to the string tension, and only the compression force is applied to the base member 10 on which the string is stretched by the string tension. Become. For this reason, bending deformation (warping) due to string tension can be prevented without increasing the rigidity of the base member 10. This eliminates any so-called neck warpage. In addition, as the base member 10, for example, a thin and light metal member as in this example can be used to achieve weight reduction, size reduction, and cost reduction. In addition, bending deformation of the base member 10 due to deterioration over time or tuning failure can be prevented, and such bending deformation can also prevent a failure in which the string height and the fret height fluctuate and become unstable, thereby reducing performance.

  In particular, in the string module 1 of this example, the base member 10 that stretches the string S is made of metal, and the frets 21 and 22 are formed integrally with the base member 10. For this reason, once the height of these frets is adjusted in the finishing process or the like in the manufacturing process of the base member 10, it does not change due to secular change or malfunction of tuning. By the way, in the case of fret instruments such as guitars, the accuracy of the fret height is required, but since the fret height was not fixed because the metal fret was hit against the wood neck in the past, the fret height was always adjusted by post-processing. Needed. This is because the neck is made of wood, which is affected by the bending of the neck and there are many unstable elements. According to the string module 1 of this example, there is no such unstable element, the string and the frets are stable, and a stringed musical instrument with high performance can be realized.

  Further, since the bending moment becomes zero, the material constituting the base member 10 is not limited to metal, and resin, glass, earthenware, inexpensive wood with low bending rigidity, and the like can be used. The degree of freedom is improved, and not only weight reduction, size reduction, and cost reduction, but also design improvement is possible.

  The string module 1 includes a string tension adjusting member 33 to which both ends of the string S are fixed. The string tension adjusting member 33 is the other end of the base member 10 on the extension of the center line M of the base member 10. It is arranged on the side, and is movable along the center line M in a direction in which the other end of the base member 10 is in contact with or separated from the other end. Therefore, by moving the string tension adjusting member 33 in the above direction (specifically, in this example, the string tension adjusting member 33 is moved by operating the adjusting nut 35 or the like as described above), the bending moment described above becomes zero. The tension of the string can be easily adjusted while maintaining the state, and tuning is easily possible.

  In the string module 1, since the string S is continuously stretched from the upper side to the lower side of the base member 10, the number of strings is smaller than that in the case where separate strings are stretched on the upper side and the lower side. The number of tuning devices such as the string tension adjusting device 11 can be halved, and the tuning operation does not have to be performed on the upper and lower surfaces. Further, since the strings are continuous in the vertical direction, the tensions of the upper and lower strings become equal without any special adjustment, which is advantageous in accurately setting the bending moment due to the string tension to zero as described above.

  In addition, when the string S becomes dirty or rusted and it is desired to replace the string S, if the upper and lower surfaces of the string module 1 are reversed and replaced, the new string S becomes the front side. There is an effect that the same result as that obtained when the strings are replaced can be easily obtained without replacing the strings. In some cases, the string module 1 for replacement can be prepared separately, and the entire string module 1 can be replaced with a new one to realize string replacement. In addition, at this time, if the tuning of each string S of the replacement string module 1 is performed in advance, the tuning after the string replacement is not essential.

Next, a second embodiment of the present invention will be described. The second embodiment includes a string vibration control member 90 shown in FIG. 9, and the other configuration except for the string vibration control member may be the same as that of the first embodiment.
As shown in FIGS. 9A and 9B, the string vibration control member 90 includes a substrate portion 91, a vibration absorbing portion 92 and a node forming portion 95 provided inside the substrate portion 91. Here, similarly to the string vibration control member 80 of the first embodiment, the board portion 91 is made of, for example, the same synthetic resin as the musical instrument case 2 and is attached so as to close the opening 41 described above. 2 and the shape and dimensions integrated with no step. As with the string vibration control member 80, attachment pieces 93 that are elastically bent and fit into the attachment recesses 42 are formed at both ends of the substrate portion 91, respectively. The mounting pieces 93 are respectively formed with engaging recesses 94 into which the above-described engaging protrusions 43 are fitted when the string vibration control member 90 is mounted. With such a configuration, like the string vibration control member 80, the string vibration control member 90 can be easily mounted with a single touch by the user by being pushed into the opening 41 of the musical instrument case 2. By pulling out from the opening 41, the user can easily remove it.

  Here, similarly to the vibration absorbing portion 82 of the first embodiment, the vibration absorbing portion 92 is made of a mute material such as silicon rubber (a material capable of absorbing the vibration of the string by contacting the string), for example, bonding It is being fixed to the inner surface of the board | substrate part 91 by. However, the vibration absorbing portion 92 is provided only at locations corresponding to the three strings S1 to S3 on the high pitch side among the six strings S1 to S6. When the string vibration control member 90 is attached to the opening 41 of the musical instrument case 2, the vibration absorbing portion 92 is attached only to the strings S1 to S3 on the back side (lower side in FIG. 9) of the base member 10. As shown in (a), the surface is in sufficient contact with the string S1 to S3 to sufficiently prevent resonance. In other words, the vibration absorbing portion 92 is configured to act only on the specific strings S1 to S3 and not to contact the other strings S4 to S6 when the string vibration control member 90 is mounted.

  Next, the node forming portion 95 is a portion that contacts the string and forms a vibration node on the string. In this example, as shown in FIG. 9C, the node forming portion 95 protrudes upward from the bottom surface of the substrate portion 91. It is comprised by the rib (rib integrated with the board | substrate part 91) provided in this. Unlike the vibration absorbing portion 92, the knot forming portion 95 is hard and is configured to contact the string with a considerable pressing force in a state where the string vibration control member 90 is mounted. A vibration node (portion that does not move up and down) is formed. That is, the chord with which the knot forming portion 95 comes into contact is divided at the position where the knot forming portion 95 comes into contact and vibrates with a chord length shorter than that in the open state. Due to the action of the knot forming portion 95, the pitch due to the vibration of the string in contact with the knot forming portion 95 is different from the pitch of the open string. As shown in FIG. 9A, the node forming portion 95 of this example is provided only at locations corresponding to the two strings S5 and S6 on the bass side of the six strings S. The vibration nodes are formed in the strings S5 and S6 in contact with S5 and S6. In the case of the second embodiment, the position of the opening 41 in the longitudinal direction (left and right direction in FIG. 2) of the instrument case 2 and each string S is the string S5 on which the node forming portion 95 acts as described above. , S6 are positions corresponding to positions where nodes in the longitudinal direction should be formed (hereinafter referred to as node forming positions). That is, when the string vibration control member 90 is attached, the position of the opening 41 in the longitudinal direction is set so that the nodes are accurately formed at predetermined node forming positions in the strings S5 and S6.

  According to the second embodiment, the string vibration control member 90 is attached to the instrument case 2 to change the vibration of the string. However, in this example, both the vibration absorbing portion 92 and the node forming portion 95 are provided in one string vibration control member 90, and the vibration absorbing portion 92 and the node forming portion 95 each act on a specific string. That is, in this example, as shown in FIG. 9A, the vibration absorbing portion 92 of the string vibration control member 90 contacts the strings S1 to S3 and absorbs the vibrations of the strings S1 to S3 on the back side. In addition, the knot forming portion 95 of the string vibration control member 90 contacts the strings S5 and S6 to form vibration knots at predetermined knot forming positions on the back strings S5 and S6. Therefore, by attaching the string vibration control member 90 to the musical instrument case 2, it is possible to eliminate the vibration of the back side strings S1 to S3 (vibration of the open side strings S1 to S3) unnecessary for performance, and the back side. The vibration of the string S4 (vibration of the open string S4) and the vibration of the strings S5 and S6 on the back side (vibration having a knot at a predetermined knot formation position of the strings S5 and S6) are actively used for performance. Performance can be improved by adding sound. In other words, when the string vibration control member 90 of this example is mounted, the strings S4 (open strings) and strings S5 and S6 (non-open strings) on the back side function as resonance strings of the sitar guitar. Here, the knot forming portion 95 contacts a predetermined knot forming position of the strings S5 and S6 on the back side, and changes the pitch due to the vibration of the strings S5 and S6 to a predetermined pitch that is different from the pitch of the open string. To change. Thereby, it is possible to change the vibration of the back side strings S5 and S6, which is unconsonant with an open string, to a sound useful for performance. Thus, the knot forming unit of the present invention can eliminate the sound of an open string unnecessary for performance and can add a sound useful for performance.

  In the above-described embodiment, the case where the number of strings is six is exemplified. However, the scope of application of the present invention is not limited to this. For example, a 12-string guitar having 12 strings may be used. A single string may be used. Also, an acoustic guitar or a stringed instrument other than a guitar may be used. Further, there may be a mode in which there is no string support portion on the other end side of the base member.

  In the above-described embodiment, the string vibration control member 80 having only the vibration absorbing portion 82 acting on all the strings S, the vibration absorbing portion 92 acting only on the strings S1 to S3, and the strings S5 and S6 act only. The string vibration control member 90 having the knot forming portion 95 is illustrated. However, the specifications of the string vibration control member of the present invention (such as the presence / absence of a vibration absorbing portion and a knot forming portion, the type and number of strings on which the vibration absorbing portion acts, the type and number of strings on which the knot forming portion acts) are various. There can be various specifications. For example, it may be a string vibration control member having only a knot forming portion, a knot forming portion acting on a specific string other than the strings S5 and S6, and a vibration absorbing portion acting on any of the remaining strings. There may be various forms such as a string vibration control member having

Moreover, although the node formation part 95 of 2nd Embodiment mentioned above has the same contact position (node formation position) of the longitudinal direction with respect to string S5, S6, it is not restricted to this. For example, a single string vibration control member may be provided with a plurality of types of node forming portions having different contact positions (node forming positions) depending on the strings.
In the above-described embodiment, the case where the string vibration control member is attached to only one part is illustrated, but the present invention is not limited to this. For example, the opening 41 may be formed at a plurality of locations in the longitudinal direction of the musical instrument case 2, and the user may select one or a plurality of locations from the plurality of locations and attach the string vibration control member. Alternatively, a plurality of string vibration control members having different specifications may be prepared, and the user may select one or a plurality of string vibration control members and attach them to the musical instrument case 2 for use.

  The present invention may also be a stringed instrument with a body in which a body portion is formed in an instrument case. For example, the guitar body is a part formed around the playing part of the guitar, and is generally a part that is held on the body when the performer holds the guitar. This is a gourd-shaped box-shaped part formed on both sides of a knee recess that hits and a chest recess that hits the chest. With such a body, the overall moment of inertia of the guitar increases (especially when sitting and playing the guitar), and the feeling of having a guitar increases as the fit with the body increases. Because it increases, a good expression is possible.

  In the above embodiment, the string module and the electromagnetic pickup are attached to the instrument case with screws, but there are many known mechanical attachment methods. For example, these string modules and electromagnetic pickups can be easily attached and detached using a known snap mechanism or lock mechanism (for example, the lever is released when the lever is tilted and fixed when the lever is returned to its original position). If the method is adopted, the string module and the like can be attached and detached more quickly. Then, when the string module is attached / detached by a mechanism other than a screw and there is no portion like the boss 29 (FIG. 2) in the first embodiment, there is an advantage that the degree of freedom of the attachment position of the string vibration control member is increased. is there. This is because in the first embodiment, it is impossible to form the opening 41 for attaching the string vibration control member at a position where the boss 29 is located. The position where the boss 29 is provided is limited to a position other than the position where the boss 29 is located. However, if the string module 1 is attached and detached by a mechanism other than a screw and there is no portion such as the boss 29 in the first embodiment, there is an advantage that such a limitation is eliminated.

  In the above-described embodiment, both ends of the string are fixed to the movable string tension adjusting member 33 and pulled together to generate tension on the string. On the other hand, when the string is stretched, one end of the string is fixed on the extension of the center line M, and only the other end is moved on the extension and fixed after being pulled. Specifically, a configuration may be adopted in which both ends of the string are fixed while being pulled. For example, as shown in FIG. 10, only the other end of the string S is fixed to the string tension adjusting member 33, and one end of the string S (in this case, the pole end SE) is, for example, on the center line M of the base member 10. There is also a mode in which the string tension adjusting member 33 is attached to the string tensioning member 61 and the string tension adjusting member 33 is moved to pull only the other end of the string S to generate a necessary tension for the string S. In this case, if the tension of the string S is the same, the force for pulling the string tension adjusting member 33 can be halved compared to the case of pulling both ends. Further, the structure of the string tension adjusting member 33 is simplified.

  Further, the base member of the present invention does not necessarily need to be vertically symmetrical. For example, the string support portion does not necessarily have to protrude at the same height on the upper and lower surfaces (one surface side and the other surface side), and there may be a mode in which the protrusion height (string height) of the string support portion differs vertically. In this case, if the tension is the same, the moment of force due to the tension of the string on the upper surface side and the moment of force due to the tension of the string on the lower surface side cancel each other and do not become zero. However, compared with the conventional configuration in which the string is stretched only on one side, the bending moment generated in the base member 10 due to the tension of the string is reduced by canceling up and down a considerable amount of the moment of the force applied to the base member due to the tension. This is much lower than before.

  Further, the base member of the present invention does not necessarily have a configuration in which strings are stretched continuously in the vertical direction. The present invention may have a mode in which the strings are stretched separately (discontinuously) on one side and the other side of the base member. FIG. 11 shows a specific example thereof.

  In the embodiment of FIG. 11, the nut fixing screw 27 and the nut fixing washer 26 of the first embodiment are deleted, and a string locking is provided at one end of the base member 10 (on the left side of the nuts 12 and 13 in FIG. 11). Portions 71 and 72 are formed on the top and bottom, respectively. Then, different string SA and string SB are stretched between the upper surface side and the lower surface side of the base member 10 by using the string locking portions 71 and 72, respectively. Each of the string locking portions 71 and 72 is formed with a through hole (reference numeral omitted) for passing the strings SA and SB. The pole end SE of each string SA, SB has a larger outer shape than this through hole. Therefore, if the other end portions of the strings SA and SB are inserted into the through holes and pulled to the other end side (the right end side in FIG. 11) of the base member 10, they are formed at one end portions of the strings SA and SB. Each pole end SE is held in contact with the string locking portions 71 and 72 as shown in FIG.

  On the other hand, on the upper surface and the lower surface of the string tension adjusting member 33, a string fixing recess 40 for fixing the other end of each string SA, SB with a string fixing screw 39 is formed. On the bottom surface of each string fixing recess 40, screw holes (reference numerals omitted) for screwing the shaft of the string fixing screw 39 are formed. The other end side of each string SA, SB is sandwiched between the bottom surface of each string fixing recess 40 and the head of each string fixing screw 39 screwed into the screw hole, whereby a string tension adjusting member is obtained. 33 is fixed to the upper surface side and the lower surface side, respectively.

The present invention may be an embodiment as shown in FIG. 11. In this case as well, for example, the same members as the above-described string vibration control members 80 and 90 can be attached to and detached from the instrument case, and the first embodiment and The same effects as in the second embodiment can be achieved.
Also in the embodiment as shown in FIG. 11, the strings SA and SB are symmetrically stretched at the same height on the upper and lower sides of the center line M of the base member 10, and the other ends of the strings SA and SB are also provided. The portion is pulled toward the direction away from the other end of the base member 10 on the extension of the center line M. For this reason, the bending moment generated in the base member 10 by the tension of the strings SA and SB cancels up and down and becomes almost zero. Also, in this case, since the strings are stretched separately at the top and bottom, in addition to being able to vary the type and arrangement of the strings at the top and bottom, the length of each string is the normal size (compared to the first embodiment). Half the length) is obtained.

  As shown in FIG. 11, when the strings are stretched up and down separately (discontinuously), the string tension adjusting device 11 is also provided separately in the top and bottom, and the upper string and the lower string are pulled separately. It is good also as a structure. If it does in this way, it is possible to set the tension | tensile_strength of a string to each predetermined | prescribed tension | tensile_strength by the upper surface side and a lower surface side. Here, “set to a predetermined tension” means, for example, setting different tensions on the upper surface side and lower surface side or the same tension depending on the type of string, performance needs, etc., or the aforementioned bending moment. In order to make the value zero, it means that the same tension or different tensions are set on the upper surface side and the lower surface side. In this case, even if the protrusion height of the string support portion is different between the upper surface side and the lower surface side, it is possible to make the above-described bending moment zero by changing the vertical tension accordingly. .

1 String module 2 Musical instrument case 10 Base member 11 String tension adjusting device 12, 13 Nut (string support member)
14,15 bridge (string support member)
33 String tension adjusting member 41 Opening portion 80, 90 String vibration control member 82, 92 Vibration absorbing portion 95 Node forming portion S, S1 to S6 String

Claims (5)

A base member with strings stretched up and down,
A musical instrument case to which the base member is attached;
A string vibration control member that is detachably attached to the instrument case and changes the vibration of the string , and
The stringed musical instrument, wherein the string vibration control member has a knot forming portion that contacts the string and forms a knot of vibration in the string.   The stringed instrument according to claim 1, wherein the string is continuously stretched from the upper side to the lower side of the base member by being folded back at one end of the base member. The instrument case is mounted with the base member in a state where the string located on the upper side of the base member is exposed,
The stringed musical instrument according to claim 1, wherein the string vibration control member acts on the string located below the base member.   The stringed musical instrument according to any one of claims 1 to 3, wherein the string vibration control member includes a vibration absorbing portion that contacts the string and absorbs vibration of the string. A plurality of the strings are stretched in parallel,
The stringed musical instrument according to claim 1, wherein the string vibration control member acts on a specific string among the plurality of strings.

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