JP2009088919A - Stringed musical instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an automatic stringed musical instrument which can be used as a stringed musical instrument and reproduces original tone of a stringed musical instrument similar to when a performer plays the instrument. <P>SOLUTION: The stringed musical instrument 1 is provided with: strings 21; a front board 11; a back board 12; a side board 13 bonding the front board 11 and the back board 12; a main body 10 provided with a hollow 14 inside; a bridge 20 provided on the front board 11 to support the strings 21; and an actuator 40 brought into contact with the bridge 20 to vibrate the bridge 20 based on an input electroacoustic signal. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a stringed musical instrument that can perform automatically.

In recent years, devices for automatically playing stringed instruments such as guitars and violins have been developed. The stringed instrument transmits vibrations from the strings mainly to the top plate of the main body through the piece, so that resonance occurs in the front plate, the back plate and the cavity inside the main body, thereby playing a deep tone. Yes. There is known a stringed musical instrument that enables automatic performance by directly vibrating a surface plate by an actuator using the sound generation mechanism of this musical instrument (Patent Document 1). An actuator using a magnetostrictive element is also known as an actuator that generates mechanical vibration (Patent Document 2).
Japanese Patent No. 3788382 Japanese Patent No. 3615883

  However, in the method disclosed in Patent Document 1, since the actuator is simply provided on the front plate of the main body, the vibration transmission path is different from that in the case where the performer actually performs. In some cases, the sound quality deteriorates as compared with the performance by the performer.

  Accordingly, an object of the present invention is to provide a stringed musical instrument that can be used as a stringed musical instrument and that can reproduce the timbre inherent to the stringed musical instrument as in the case of a performance by a performer.

  In order to achieve the above object, a stringed musical instrument of the present invention has a string, a front plate, a back plate, a side plate that joins the front plate and the back plate, a main body having a cavity inside, and provided on the front plate. A piece that supports the string, and an actuator that applies vibration to the piece based on the input electroacoustic signal.

  When a performer vibrates a stringed instrument, the vibration is transmitted to the top plate of the main body through the piece, and the front plate, the back plate, and the cavity of the main body resonate to emit sound. Here, the piece is provided at an appropriate position so that, when the performer performs, the string vibration is applied to the front plate to produce a sound having a depth as a whole.

  On the other hand, when an electroacoustic signal is input and the actuator is vibrated based on the electroacoustic signal, the vibration from the actuator is transmitted to the top plate of the main body through the piece, and the performer vibrates the string. As in the case, the front plate, the back plate, and the cavity of the main body resonate to generate sound. In this way, when an electroacoustic signal is input and an automatic performance is performed, vibration is transmitted through the piece in the same way as when the string is vibrated, so that the stringed instrument is essentially the same as when played by the performer. Automatic performance that reproduces the tone you have is possible.

  In the present invention, an actuator having a vibration output portion at one end is provided inside the cavity of the main body, and further has a through hole communicating with the cavity in the front plate, and the vibration output portion is in contact with the piece through the through hole, It is preferable that they are arranged so as to give vibration. The possibility that the resonance space originally provided by the stringed instrument is damaged is reduced, and the stringed instrument can be brought closer to the original tone. In addition, since the actuator is disposed inside the cavity and the vibration output portion is exposed to the outside of the stringed instrument from the through hole, the appearance of the stringed instrument is not impaired.

  The stringed instrument of the present invention preferably further includes an elastic member sandwiched between the other end of the actuator and the back plate of the stringed instrument. According to this configuration, not only the actuator is supported and fixed by the elastic member, but also the vibration of the actuator is absorbed by the elastic member, so that it is possible to suppress the vibration from being directly transmitted from the actuator to the back plate.

  The stringed musical instrument of the present invention preferably includes a beam provided so as to connect the side plates facing each other and to support the other end of the actuator. Since the beam connecting the side plates supports the actuator, it is possible to prevent the vibration of the actuator from being transmitted directly to the back plate, and to prevent deterioration in sound quality.

According to the present invention, it is possible to provide a stringed musical instrument that can be used as a stringed musical instrument and can perform automatic performance that reproduces the original tone color of the stringed musical instrument as if it were performed by a performer.

<First embodiment>
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<Overall configuration>
FIG. 1 is a perspective view showing the overall configuration of a violin that is an embodiment of the stringed musical instrument of the present invention. FIG. 2 is a cross-sectional view showing the internal structure of the violin. The violin 1 of this embodiment includes a main body 10, a neck 30 provided at one end of the main body 10, a tail piece 32 provided at the other end of the main body 10, and a tail piece 32 from the tip of the neck 30. It has the string 21 stretched over.

  The main body 10 includes a front plate 11, a back plate 12, and a side plate 13 that joins the peripheral edges of the front plate 11 and the back plate 12, and a cavity 14 formed by the front plate 11, the back plate 12, and the side plate 13. Inside. In the cavity 14, there is a soul column 22 sandwiched between the front plate 11 and the back plate 12. The front plate 11, the back plate 12, the side plate 13, and the soul pillar 22 that form the main body 10 are all made of a wooden material.

  The front plate 11 of the main body 10 is provided with an f-shaped hole 33 so that sound resonated in the cavity 14 is transmitted to the outside through the f-shaped hole 33. Further, a piece 20 for supporting the string 21 from below is provided near the center of the front plate 11 of the main body 10. An actuator 40 is in contact with the piece 20, and vibration generated by the actuator 40 is transmitted to the piece 20.

  At the tip of the neck 30, a bobbin 31 for locking one end of the string 21 is provided. The tail piece 32 is provided with an engaging portion for locking the other end of the string 21.

  One end of the string 21 is fixed by a tail piece 32 on the front plate 11, and the other end is wound around a bobbin 31 provided at the tip of the neck 30. The string 21 is supported from below by the upper end of the piece 20 in the vicinity of the center of the main body 10, and by adjusting the length of the string 21 by turning the bobbin 31, the upper end of the piece 20 can be played. Is supported as a supporting point.

  The soul column 22 is a cylindrical member that is fixed without using an adhesive while being sandwiched between the front plate 11 and the back plate 12 so as not to contact the piece 20 and the actuator 40. The soul column 22 transmits the vibration applied to the front plate 11 from the piece 20 to the back plate 12 and contributes to the vibration and sound generation of the main body 10.

  The piece 20 is a wooden member that transmits vibration from the actuator 40 or the string 21 to the front plate 11. The violin 1 receives the vibration from the piece 20 by the front plate 11, and the vibration is transmitted from the front plate 11 to the back plate 12 through the soul pillar 22 and the side plate 13, and each plate and the cavity 14 resonate to generate sound. To emit. When vibration is input from the actuator 40, the actuator 40 can vibrate the piece 20 for automatic performance. However, when the actuator is not used, the player vibrates the string 21 with a bow (not shown). The string 21 vibrates the piece 20 and can be played.

  The piece 20 is provided on the front plate 11 and has a role of transmitting vibration from the string 21 to the front plate 11. A stringed instrument emits sound from the instrument body to the outside mainly by vibrating the surface plate 11. The position of the piece 20 is to optimize the vibration of the front plate 11 and the other back plate 12, side plate 13, soul column 22 and cavity 14 of the stringed instrument to be played, and to produce a deep tone that the stringed instrument originally has. Is fine-tuned to the optimal position. The piece 20 of the present embodiment is also provided at the same position as that originally provided on the violin 1 using the front plate 11. Since the piece 20 is provided at an accurate position, the timbre inherent in the violin 1 can be played even when the performer performs, or during automatic performance by vibration transmission from the actuator 40.

  The piece 20 is a plate-like member formed in a circular arc shape with one end divided into two forks and the other end rounded, and is perpendicular to the front plate 11 and also perpendicular to the string 21. It is provided as follows. One end of the piece 20 is temporarily fixed by engaging a recess or hole (not shown) provided in the front plate 11 without using an adhesive or the like, and the other end is a string. 21, and is fixed between the string 21 and the front plate 11 by an urging force applied from the string 21. Therefore, when the string 21 is loosened, the piece 20 is released from being fixed and is not in a state perpendicular to the front plate 11. The reason why the piece 20 is not fixed with an adhesive or the like in this way is not preferable because an adhesive or the like enters between the piece 20 and the front plate 11 and good vibration transmission from the piece 20 to the front plate 11 is impaired. Because.

  As described above, one end of the bifurcated piece 20 is in contact with the front plate 11, and a through hole 15 communicating with the cavity 14 is provided between the contact points A and B of the front plate 11. It has been. The actuator 40 is disposed in the cavity 14. A vibration output portion 41 is provided at one end of the actuator 40, and the vibration output portion 41 is exposed to the outside through the through hole 15. The tip of the vibration output unit 41 is in contact with the bifurcated root portion of the piece 20, and vibration generated by the actuator 40 is applied to the piece 20 through the vibration output unit 41.

  Further, the vibration output unit 41 is disposed without contacting the inner wall of the through hole 15. When it comes into contact with the inner wall of the through hole 15, vibration is directly transmitted from the vibration output portion 41 to the front plate 11, and therefore vibration transmission from the piece 20 provided at an optimum position with respect to the front plate 11 is performed. Impedes and degrades sound quality. If the diameter of the through hole 15 is too large, the resonance state in the cavity 14 may be hindered. Therefore, the through hole 15 is as small as possible and has a diameter that does not contact the vibration output portion 41. preferable.

  On the other hand, an elastic member 16 made of, for example, silicon rubber is sandwiched between the other end of the actuator 40 and the back plate 12. In this case, the actuator 40 is sandwiched and fixed between the piece 20 fixed by stretching the string 21 and the elastic member 16 supported by the back plate 12. Since the elastic member 16 is interposed between the other end of the actuator 40 and the back plate 12, the vibration of the actuator 40 is absorbed by the elastic member, so that the vibration directly transmitted from the actuator 40 to the back plate 12 is reduced. Can be made. As described above, by reducing the vibration transmission to the back plate from other than the soul column 22 and the side plate 13, it is possible to prevent the sound quality of the violin 1 from being deteriorated.

<Configuration of actuator>
Various actuators such as a piezoelectric actuator and a magnetostrictive actuator can be used as the actuator 40. In this embodiment, an example using a magnetostrictive actuator will be described.

  FIG. 3 is a front sectional view of an actuator 40 which is a magnetostrictive actuator. The actuator 40 includes a vibration output unit 41, an exterior body 42, a pressurizing member 43, a magnetostrictive element 44, a permanent magnet 45, a yoke member 46, a coil 47, and a bobbin 48.

  The exterior body 42 is made of a rigid material such as a metal material, and has an internal space 49 and a bottom portion 50. The exterior body 42 has a structure in which the bottom portion 50 is fitted into one end of the cylindrical portion 51 and is fixed by a stopper 52 such as a screw, and has an opening 53 on the side facing the bottom portion 50. Yes.

  The opening 53 has an inward flange portion 54 formed at the other end of the cylindrical portion 51. The vibration output unit 41, the pressurizing member 43, the magnetostrictive element 44, the permanent magnet 45, the yoke member 46, the coil 47, and the bobbin 48 are accommodated in the internal space 49 of the exterior body 42.

  The bobbin 48 has a cylindrical portion 55 and flange portions 56 and 57 at both ends thereof, and the coil 47 is wound around the outer peripheral surface of the cylindrical portion 55 of the bobbin 48. A rod-shaped magnetostrictive element 44 is inserted into the cylindrical portion 55 of the bobbin 48. The flange portion 56 of the bobbin 48 is fitted into a step portion 60 provided on the inner surface of the bottom portion 50. The magnetostrictive element 44 has one end abutting against the stepped portion 60 and is received by the bottom portion 50.

  The permanent magnet 45 is formed of a cylindrical body, and houses the magnetostrictive element 44, the coil 47, and the bobbin 48 inside. The permanent magnet 45 is disposed in the internal space 49 of the exterior body 42. The other end is received by a step portion 61 formed on the inner wall surface of the internal space 49 of the exterior body 42.

  The yoke member 46 is an annular disc body having a through-hole 62 penetrating in the thickness direction at the center. The yoke member 46 forms a quasi-closed magnetic path together with the permanent magnet 45 and the bottom 50 and applies a magnetic bias to the magnetostrictive element 44.

  One end side of the vibration output unit 41 is connected to the other end side of the magnetostrictive element 44 through the through-hole 62, and the other end is guided to the outside through the opening 53. The vibration output unit 41 is preferably made of a material mainly composed of a polymer material. The vibration output unit 41 is provided with a recess 63 for receiving the magnetostrictive element 44 on one end side connected to the magnetostrictive element 44. The body part 64 of the vibration output part 41 has a stepped shape, and a collar part 65 is provided at the rear end part of the body part 64.

  The pressurizing member 43 is interposed between the exterior body 42 and the vibration output unit 41 and biases the vibration output unit 41 toward the magnetostrictive element 44. The pressurizing member 43 may be a metal plate spring or a metal coil spring, but is preferably an elastic material mainly composed of a polymer material. Specifically, it is a polymer rubber or a polymer plastic having a certain elastic modulus. These may be a single polymer material or a composite material obtained by adding inorganic powder or the like to the polymer material. In this case, the pressurizing member 43 has a cylindrical shape, one end of the cylindrical body viewed in the axial direction is received by the exterior body 42, and the other end is a step portion 66 configured by the collar portion 65 of the vibration output portion 41. Received by. The pressurizing member 43 is disposed so as to surround the trunk portion 64 of the vibration output portion 41, and includes a step portion 66 constituted by a collar portion 65 provided at an end portion of the trunk portion 64, and a collar portion 68 of the spacer 67. Compressed with the step portion 69.

  The spacer 67 is inserted between the exterior body 42 and the vibration output unit 41. The spacer 67 is also preferably made of a material mainly composed of a polymer material. The spacer 67 has a collar portion 68, and the collar portion 68 overlaps and is supported by the inner surface 70 of the inwardly-facing collar portion 54 of the exterior body 42.

  Thus, in the actuator 40 having such a configuration, by passing an electroacoustic signal obtained by a receiver described later through the coil 47, a magnetic field based on the electroacoustic signal is applied to the magnetostrictive element 44, and the magnetostrictive element 44 is electroacoustic. It can be expanded and contracted according to the signal. The expansion and contraction of the magnetostrictive element 44 is transmitted to the vibration output unit 41 as mechanical vibration and is output to the outside through the vibration output unit 41. As described above, in the present embodiment, since the vibration output unit 41 is in contact with the piece 20, vibration based on the electroacoustic signal can be transmitted to the piece 20.

<Receiver configuration>
In the violin 1 of this embodiment described with reference to FIGS. 1 and 2, a receiver (not shown) is provided in the cavity 14 of the main body 10, and an actuator 40 transmitted from the outside is driven by the receiver. And receiving the electroacoustic signal to the actuator 40 to generate vibration based on the electroacoustic signal.

  FIG. 4 is a block diagram illustrating a configuration of a receiver provided in the main body 10 and a transmitter that transmits an electroacoustic signal to the receiver. As shown in FIG. 4, the transmitter 80 is connected to a music playback device that plays back music data recorded on a semiconductor memory, a hard disk drive, an optical disk or the like, a so-called playback player 81. In this case, the music data is violin performance data. The music data reproduced by the reproduction player 81 is converted into an analog electroacoustic signal and output from the reproduction player 81. In this case, the electroacoustic signal output from the playback player 81 is an electrical signal indicating the performance sound of the violin. The electroacoustic signal is input to the transmission circuit 82, where signal processing based on a predetermined communication method is performed, and a radio signal based on the electroacoustic signal is generated. This radio signal is transmitted via the transmission antenna 83.

  On the other hand, the receiver 90 includes a reception antenna 91 and a reception circuit 92, and the reception antenna 91 receives a radio signal transmitted from the transmission antenna 83. The received radio signal is sent to the receiving circuit 92, where the electroacoustic signal is restored by performing a predetermined receiving process, and is supplied to the actuator 40 as a driving signal for the actuator 40 as described above. Thus, by supplying the electroacoustic signal to the internal coil in the actuator 40, vibration based on the electroacoustic signal can be generated.

  Although not shown here, the receiver 90 is provided with an operation switch. By turning off the operation switch, the supply of the electroacoustic signal to the actuator 40 can be stopped, and an automatic performance by the actuator 40 can be performed. Stopping and normal performance by the performer is also possible. In that case, the performer only has to vibrate the string 21 with a bow, like a normal violin.

<Second Embodiment>
FIG. 5 shows a cross-sectional view of a violin 100 according to the second embodiment of the present invention. In addition, the same code | symbol is attached | subjected to the part similar to the part demonstrated in FIG. 2, such as the piece 20 and the actuator 40, and the detailed description is abbreviate | omitted.

  A wooden beam 17 that connects the side plates 13 is provided in the cavity 14. Unlike the first embodiment, the actuator 40 is fixed between the beam 17 and the piece 20.

  According to this configuration, since the actuator 40 is disposed without being in direct contact with the back plate 12, it is possible to prevent vibration from being directly transmitted from the actuator 40 to the back plate 12, and to prevent deterioration in sound quality. . Since the beam 17 can reduce the bonding area with the side plate 13 and the resonance of the stringed instrument is considered to be mainly caused by the front plate 11 and the back plate 12, even if the vibration is transmitted, the influence on the sound quality is reduced. In this configuration, the soul pillar 22 is responsible for transmitting vibration from the front plate 11 to the back plate 12, so that the vibration of the front plate 11 and the back plate 12 is close to the vibration state similar to that of a normal violin. It can be brought close to the tone of.

<Other embodiments>
The present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention, and these are also included in the scope of the present invention. Needless to say.

  For example, in the second embodiment described above, the actuator 40 is supported by the beam 17. However, the present invention is not limited to this, and the beam 17 and the actuator 40 are interposed between the beam 17 and the actuator 40 as in the first embodiment. An elastic member may be interposed.

  In both the first embodiment and the second embodiment, the actuator 40 is disposed inside the cavity 14. However, the actuator 40 is disposed outside the violin body 10 so as to contact the piece 20. Also good.

  Further, in each of the above embodiments, the vibration output unit 41 of the actuator 40 and the piece 20 are in direct contact. However, as long as vibration from the actuator 40 is directly transmitted to the piece 20, there is some member between them. It may be interposed.

It is a perspective view of the violin 1 which is 1st embodiment. It is sectional drawing of the violin 1 which is 1st embodiment. 3 is an internal cross-sectional view of an actuator 40. FIG. It is a block diagram which shows the structure of a transmitter and a receiver. It is sectional drawing of the violin 100 which is 2nd embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,100 ... Violin 10 ... Main body 11 ... Front board 12 ... Back board 13 ... Side board 14 ... Cavity 15 ... Through-hole 16 ... Elastic member 17 ... Beam 33 ... F-shaped hole 20 ... Piece 21 ... String 22 ... Soul pillar 30 ... Neck 31 ... spool 32 ... tail piece 40 ... actuator 41 ... vibration output part 42 ... exterior body 43 ... pressurizing member 44 ... magnetostrictive element 45 ... permanent magnet 46 ... yoke member 47 ... coil 48 ... bobbin

Claims (5)

Strings,
A main body having a front plate, a back plate and a side plate for joining the front plate and the back plate, and having a cavity inside;
A piece provided on the front plate and supporting the string;
An actuator for giving vibration to the piece based on the input electroacoustic signal;
A stringed instrument characterized by comprising: The main body has a through hole provided in the front plate so as to communicate with the cavity,
The actuator has a vibration output portion provided at one end,
The stringed instrument according to claim 1, wherein the actuator is disposed in the cavity so that the vibration output unit contacts the piece through the through hole. An elastic member sandwiched between the other end of the actuator and the back plate;
The stringed instrument according to claim 2, wherein: The main body further includes a beam provided to connect the side plates facing each other and to support the other end of the actuator.
The stringed instrument according to claim 2, wherein: The actuator is a magnetostrictive actuator;
The stringed instrument according to any one of claims 1 to 4, wherein the stringed instrument is characterized.

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