JP6031760B2 - Musical instruments, grand pianos and upright pianos - Google Patents

Description

  The present invention relates to a technique for improving the acoustic characteristics of a musical instrument.

  Patent Document 1 discloses a technique for improving the acoustic characteristics of a grand piano that is a keyboard instrument. The grand piano disclosed in this document includes a shelf board and a large roof that are opposed to each other with a curved side plate, a string and an action mechanism disposed in a space surrounded by these, and a front part on the shelf board. And an arranged key. In this grand piano, the large roof is divided into two plates, a rear part at the front of the roof and a rear part at the rear. And in this grand piano, two plates of the roof rear front part and the roof rear rear part are connected side by side to the upper end of the left wall among the two parallel facing walls in the curved side plate, It can be opened and closed individually. In this grand piano, when the rear part of the roof is opened and the rear part of the roof is closed, the musical sound in the high range (string striking sound) is emphasized rather than the low tone (string striking sound). . When the rear part of the roof is closed and the rear part of the roof is opened, the musical sound in the low range (string striking sound) is emphasized and pronounced rather than the musical sound in the high range (string striking sound). Therefore, according to this grand piano, when performing a performance with an emphasis on the high range or a performance with an emphasis on the low range, it is possible to realize acoustic characteristics suitable for each.

JP 2001-83960 A

  By the way, in a grand piano, coloration occurs when a strong primary reflected sound is radiated from the roof. Coloration is a phenomenon in which the timbre of the sound changes due to interference between the direct sound emitted by the strings that are the sound source of the grand piano and the reflected sound reflected by the wall surface such as the roof. In the session of the grand piano and percussion musicians, the microphone installation position is adjusted so that the listener can hear the well-tuned sound of the grand piano as a pleasant sound. However, in general, it is difficult to adjust the installation position of such a microphone, and a high level of technology is required.

  In an upright piano, coloration occurs due to reciprocal reflection of sound between wall surfaces facing each other across a string in a rectangular parallelepiped casing. In the case of an upright piano, as in the case of a grand piano, it is difficult to perform installation work to make a sound with a good coloration a pleasant sound. Moreover, in the case of an upright piano, it is often installed with a gap of about 10 cm between the wall surface. Here, the 10 cm space between the back and the wall of the upright piano may be considered as a two-dimensional sound field, and if a piano sound is emitted in this two-dimensional sound field, a hazy and unpleasant coloration occurs. Cheap. In order to prevent such unpleasant coloration, it is also conceivable to install the upright piano at a position sufficiently away from the wall surface, or at an angle to the wall surface. However, this increases the wasted space between the back surface of the upright piano and the wall surface, which causes a problem that the space available in the room is reduced.

  In order to prevent the occurrence of unpleasant coloration in the upright piano, it is also conceivable to arrange a normal sound absorbing material between the back surface of the upright piano and the wall surface. If this sound absorbing material is used, the coloration can be reduced to some extent. However, in the narrow space between the back of the upright piano and the wall surface, it is generally difficult to suppress the low-frequency sound generated by the coloration with the sound absorbing material. There is a problem that it cannot be suppressed and it is difficult to suppress sound caused by coloration in a wide band in a balanced manner.

  The present invention has been made in view of such problems, and an object of the present invention is to provide technical means for suitably controlling coloration in keyboard instruments such as grand pianos and upright pianos.

  The present invention relates to a housing, a sounding body provided in the housing, and an acoustic structure housed in the housing, wherein a plurality of pipes each having an opening provided on a side surface surrounding each internal cavity There is provided a musical instrument having an acoustic structure in which are arranged. In this invention, each pipe in the acoustic structure in the housing generates a sound absorption effect and a scattering effect. Therefore, according to this musical instrument, the coloration in the housing can be suitably controlled.

It is a front view of the grand piano which is 1st Embodiment of this invention. It is the figure which looked at the grand piano of FIG. 1 from upper direction. It is the figure which looked at the grand piano of FIG. 1 from the arrow A direction. It is a figure which shows the string in the housing | casing in the grand piano of FIG. 1, an action mechanism, and a damper mechanism. It is a figure which shows the principle of generation | occurrence | production of the sound absorption effect and the scattering effect by the acoustic structure of the grand piano of FIG. It is a front view of the upright piano which is 2nd Embodiment of this invention. FIG. 7 is a cross-sectional view taken along line A-A ′ of the grand piano in FIG. 6. It is a perspective view of the cajon which is 3rd Embodiment of this invention. It is A-A 'sectional view taken on the line of the cajon of FIG.

Embodiments of the present invention will be described below with reference to the drawings.
<First Embodiment>
FIG. 1 is a front view of a grand piano 10 according to a first embodiment of the present invention. FIG. 2 is a view of the grand piano 10 as viewed from above. FIG. 3 is a view of the acoustic structure 1 in FIG. 1 as viewed in the A direction. A housing 11 of the piano 10 includes a shelf board 12, a curved side plate 13 fixed along the edge of the shelf board 12, and a frontal bridge installed between parallel facing wall surfaces 41L and 41R of the curved side plate 13. 14, a large roof 15 connected to the rear side of the front rod 14 on the wall surface 41 </ b> L of the curved side plate 13, a thrust bar 16 connected to the rear side of the front rod 14 on the wall surface 41 </ b> R of the curved side plate 13, and the large roof The front roof 17 is swingably connected to the front end of the pedal 15; the pedal leg columns 18L and 18R extending downward from the middle of the front end portion of the back surface 44 of the shelf board 12; and the pedal leg columns 18L and 18R The pedal box 19 is fixed to the front end, and the legs 20L, 20R, and 20C extend downward from the left and right sides of the pedal legs 18L and 18R on the back surface 44 of the shelf board 12 and the respective deep portions.

  Casters 21L, 21R, and 21C are fixed to the tips of the legs 20L, 20R, and 20C, respectively. From the front surface of the pedal box 19, a soft pedal 22, a sostenuto pedal 23, and a damper pedal 24 that are operators operated by the performer's feet are exposed. Further, the key 25-i (i = 1 to 88) is exposed from the opening surrounded by the wall surfaces 41 </ b> L and 41 </ b> R of the bent side plate 13 in the housing 11, the shelf plate 12, and the forehead 14. A keyboard lid 26 is provided at the lower end of the forehead 14, and a musical score plate 27 is provided above the forehead 14.

  As shown in FIG. 4, on the shelf 12 of the housing 11, a key 30-i (i = 1 to 88) is a member that supports the key 25-i (i = 1 to 88) in a swingable manner. Is fixed. The front 31-i and the rear 32-i are arranged in front and rear of each of the center 30-i (i = 1 to 88) on the shelf board 12. A string 33-i, which is a sounding body, is stretched above each key 25-i in a space surrounded by the bent side plate 13 and the front wing 14 of the housing 11. An action mechanism 35-i and a damper mechanism 37-i are provided behind each key 25-i in this space. The action mechanism 35-i is a mechanism that converts a key pressing force with which the performer's finger presses the key 25-i into a string hitting force with which the hammer 34-i hits the string 33-i. The damper mechanism 37-i is a mechanism that converts the stepping force by which the player's foot depresses the pedal 22 into a string separation force that separates the damper 36-i on the string 33-i from the string 33-i.

  2 and 3, the acoustic structure 1 integrated with the large roof 15 is on the surface of the large roof 15 of the piano 10 facing the space in the housing 11. The acoustic structure 1 includes a plurality of pipes 2-m (m = 1 to 10) in which openings 3-m (m = 1 to 10) are provided on side surfaces surrounding the internal cavities. is there. Each pipe 2-m in the acoustic structure 1 has side surfaces FW and BW opposed in the length direction, side surfaces UW and DW opposed in the thickness direction, and side surfaces LW and RW opposed in the width direction. Here, in FIG.1 and FIG.3, the illustration of the code | symbol of the side surfaces FW, BW, UW, DW, LW, and RW in each of the pipes 2-2 to 2-10 except the pipe 2-1 is omitted for convenience. .

  The length D1 of the pipe 2-1, the length D2 of the pipe 2-2, the length D3 of the pipe 2-3, the length D4 of the pipe 2-4, the length D5 of the pipe 2-5, and the pipe 2-6 The magnitude relationship among the length D6, the length D7 of the pipe 2-7, the length D8 of the pipe 2-8, the length D9 of the pipe 2-9, and the length D10 of the pipe 2-10 is D1 = D2 = D3. > D4> D5> D6> D7> D8> D9> D10. The pipes 2-m (m = 1 to 10) are arranged in the width direction with the side surface FW on the front wing 14 side aligned. The opening portion 3-m of the pipe 2-m is provided on one side surface DW of the side surfaces UW and DW that face each other in the thickness direction of the pipe 2-m. The side surface DW of the pipe 2-m (m = 1 to 10) forms a uniform baffle surface. The pipe 2-m (m = 1 to 10) is fixed to the large roof 15 with the other side surface DW facing the large roof 15 side. Accordingly, when the large roof 15 of the piano 10 is swung in the direction of arrow B in FIG. 1 and the space above the space in the housing 11 is closed by the large roof 15, the strings 33-i (i = 1 to 88) in this space. ) And the side surface DW of the pipe 2-m (m = 1 to 10) face each other.

The above is the details of the configuration of the present embodiment. In the present embodiment, the grand piano 10 itself that is a keyboard instrument has the acoustic structure 1. Each of the pipes 2-m (m = 1 to 10) of the acoustic structure 1 generates a sound absorption effect and a scattering effect. The principle of the sound absorption effect and the scattering effect by the pipe 2-m is as follows. As shown in FIG. 5, the inner cavity of the opening 3-m of the pipe 2-m of the acoustic structure 1, closes the end 90 L _-m in the left cavity and an opening 3-m with open end it can be considered a closed pipe CP _L to the end, and the closed tube CP _R to the right end 90 R _-m the closed end of the cavity and the openings 3-m and the open end is formed. When sound waves into the cavity through the opening 3-m enters from the acoustic space, the cavity, towards the closed end from the open end of the closed pipe CP _L (opening 3-m) (end 90 L _-m) progression and waves, the traveling wave is generated toward the open end of the closed pipe CP _R closed end (opening 3-m) (end ₉₀ R -m). The traveling wave of the former is reflected at the closed end of the closed pipe CP _L, the reflected wave is returned to the opening 3-m. The latter of the traveling wave is reflected at the closed end of the closed pipe CP _R, the reflected wave is returned to the opening 3-m.

Then, in the closed pipe CP _L, and resonance occurs at the resonant frequency _f L -k represented by the following formula (1) (k = 1,2 ... ), sound waves obtained by synthesizing the traveling wave and the reflected wave in the closed tube CP _L is have the section of the particle velocity in the closed end of the closed pipe CP _L, a standing wave having abdominal particle velocity in the open end. Also, the closed pipe CP _R, and resonance occurs at the resonant frequency _f R -k represented by the following formula (2) (k = 1,2 ... ), sound waves obtained by synthesizing the traveling wave and the reflected wave in the closed tube CP _R is have the section of the particle velocity in the closed end of the closed pipe CP _R, a standing wave having abdominal particle velocity in the open end. In the following formulas (1) and (2), L _L is the length of the closed pipe CP _L (the length from the left end 90 _L -m of the cavity to the opening 3-m), and _LR is the closed pipe CP. The length of _R (the length from the right end 90 _R -m of the cavity to the opening 3-m), c is the propagation velocity of the sound wave, and k is an integer of 1 or more.
f _L −k = (2k−1) · (c / (4 · L _L )) (1)
f _R −k = (2k−1) · (c / (4 · L _R )) (2)

Here, components of the resonant frequency f _L -k of sound waves radiated into reflected in the acoustic space from the opening 3-m in the closed end of the closed pipe CP _L is incident from the acoustic space in the opening 3-m waves The sound wave has a phase opposite to that of the resonance frequency f _L -k. On the other hand, in the vicinity of the opening 3-m on the side surface DW, the incident wave from the acoustic space is reflected without accompanying phase rotation.

Therefore, if the sound wave containing components of the resonant frequency f _L -k enters the cavity through the opening 3-m, in front of the opening 3-m in side DW (direction of arrival of the incident wave), closed tube CP _L The sound wave radiated from the opening 3-m and the sound wave reflected from each point in the vicinity of the opening 3-m on the side surface DW are in opposite phases and interfere with each other, producing a sound absorption effect. To do. Further, around the opening 3-m on the side surface DW, the phase of the sound wave from the opening 3-m and the reflected wave from the side surface DW becomes discontinuous, and the flow of gas molecules trying to eliminate the phase discontinuity occurs. Occur. As a result, a flow of acoustic energy in a direction other than the specular reflection direction with respect to the incident wave occurs around the opening 3-m in the side surface DW, and a scattering effect occurs.

Similarly, when a sound wave including a component of the resonance frequency f _R -k is incident on the cavity via the opening 3-m, a sound absorption effect is generated on the front surface (incident direction) of the opening 3-m on the side surface DW. . In addition, a scattering effect occurs around the opening 3-m on the side surface DW.

Further, in the frequency band in the vicinity of each of the resonance frequencies f _L -k and f _R -k, even if the frequency is deviated from the resonance frequency f _L -k or f _R -k, if the frequency is close to some extent, the opening 3 The phase of the sound wave radiated from -m to the acoustic space and the phase of the reflected wave radiated from the side surface DW to the acoustic space have a relationship close to an opposite phase. Therefore, in the frequency band of each vicinity of the resonance frequency f _L -k and f _R -k, sound absorbing effect and scattering effect of degree depending on the proximity of the frequency to the resonant frequency f _L -k and f _R -k Occur. The above is the principle of the sound absorption effect and the scattering effect generated by the pipe 2-m.

  As shown in FIGS. 2 and 3, in the plurality of pipes having the same length or a plurality of pipes having close lengths in the acoustic structure 1, the position of the opening in the length direction of each pipe differs for each pipe. ing. Therefore, according to the present embodiment, it is possible to generate the sound absorption effect and the scattering effect in a wide band over the range of all sounds generated in the grand piano 10. Therefore, according to the present embodiment, the coloration generated in the grand piano 10 can be controlled in a wide band.

Second Embodiment
FIG. 6 is a perspective view of an upright piano 50 according to the second embodiment of the present invention. 7 is a cross-sectional view taken along line AA ′ of FIG. A housing 51 of the piano 50 includes an upper front plate 52 and a lower front plate 53 that are arranged in a vertical direction at intervals, a rear plate 54 that faces the two plates 52 and 53, and plates 52 and 53. , And 54 from the left and right sides, and the rear roof 56 and the front roof 57 covering the upper ends of the plates 52, 53, 54, 55L and 55R, the lower end of the plate 52, the upper end of the plate 53, the plate Projecting forward from the left and right ends of the lower part of the board 53, the shelf board 59, the front arm 59, the arms 60L and 60R projecting forward from the opening surrounded by the inner wall surface of 55L, 55R And the pedestals 62L and 62R installed between the back surface of the shelf board 58 and the wife bases 61L and 61R.

  A soft pedal 63, a sostenuto pedal 64, a damper pedal 65, and an opening area adjustment pedal 66 that are operators operated by the performer's feet are exposed from the center below the lower front plate 53 in the casing 51. The role of the opening area adjustment pedal 66 will be described in detail later. A keyboard lid 75 is provided at the front end of the forehead 59. Keys 63-i (i = 1 to 88) are arranged between the arms 60 </ b> L and 60 </ b> R on the shelf plate 58 of the casing 51. The key 63-i (i = 1 to 88) is supported by the cage 64-i (i = 1 to 88) on the shelf 58. A front 65-i and a rear 66-i are disposed in front and rear of each of the baskets 64-i (i = 1 to 88) on the shelf 58. In the space surrounded by the plates 52, 53, 54, 56, and 57 of the casing 51, there is a soundboard 72 in front of the rear plate 54. Keys 63-i (i = 1 to 88) in the soundboard 72 are provided. A string 67-i (i = 1 to 88), which is a sound generator, is stretched on the surface facing the). An action mechanism 69-i and a damper mechanism 71-i are provided above the rear end of the key 63-i. The action mechanism 69-i is a mechanism that converts a key pressing force with which the performer's finger presses the key 63-i into a string hitting force with which the hammer 68-i hits the string 67-i. The damper mechanism 71-i applies the stepping force by which the performer's foot depresses the pedal 65 to the damper 70-i (i = 1 to 88) on the string 67-i (i = 1 to 88). = 1 to 88).

  On the surface of the upper front plate 52 of the piano 50 facing the soundboard 72, there is an acoustic structure 5A integrated with the upper front plate 52. On the surface of the lower front plate 53 of the piano 50 facing the soundboard 72, there is an acoustic structure 5B integrated with the lower front plate 53. The acoustic structure 5A is configured by arranging a plurality of pipes 6A-n (n = 1 to 4) provided with openings 7A-n (n = 1 to 4) on side surfaces surrounding the respective internal cavities. . The acoustic structure 5B is configured by arranging a plurality of pipes 6B-j (j = 1 to 5) in which openings 7B-j (j = 1 to 5) are provided on the side surfaces surrounding the internal cavities. .

  The pipes 6A-n of the acoustic structure 5A and the pipes 6B-j of the acoustic structure 5B have side surfaces LW ′ and RW ′ facing in the length direction, side surfaces FW ′ and BW ′ facing in the thickness direction, and width. It has side surfaces UW ′ and DW ′ that face each other. Here, in FIG. 6 and FIG. 7, for the sake of simplicity, the reference numerals of the respective surfaces except the side surfaces FW ′, BW ′, UW ′, and DW ′ of the pipe 6 </ b> B- 1 are omitted. The lengths of the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) are the same. The pipes 6A-n (n = 1 to 4) of the acoustic structure 5A are arranged in the width direction with the side surfaces LW ′ and RW ′ aligned. The side surface FW ′ of the pipe 6 </ b> A-n (n = 1 to 4) is joined to the surface of the upper front plate 52 facing the soundboard 72. The pipes 6B-j (j = 1 to 5) of the acoustic structure 5B are arranged in the width direction with the side surfaces LW ′ and RW ′ aligned. The side surface FW ′ of the pipe 6B-j (j = 1 to 5) is joined to the surface of the lower front plate 53 facing the soundboard 72.

  The opening 7A-n of each pipe 6A-n of the acoustic structure 5A is provided on the side surface BW 'of the pipe 6A-n. The opening 7B-j of each pipe 6B-j of the acoustic structure 5B is provided on the side surface BW 'of the pipe 6B-j. The position of the opening 7A-n (n = 1 to 4) in the length direction of the pipe 6A-n (n = 1 to 4) and the opening in the length direction of the pipe 6B-j (j = 1 to 5) The position of 7B-j (j = 1 to 5) is different for each pipe. Rails 9AU-n and 9AD-n (not shown) are provided above and below the opening 7A-n in the side surface BW 'of each pipe 6A-n of the acoustic structure 5A. The rails 9AU-n and 9AD-n are fitted with upper and lower ends of sheet-like shielding members 8A-n (not shown). The shielding members 8A-n are biased toward the parent plate 55L (left direction) by an elastic body (not shown). Rails 9BU-j and 9BD-j are provided above and below the opening 7B-j in the side surface BW 'of each pipe 6A-j of the acoustic structure 5B. The upper and lower ends of the sheet-like shielding member 8B-j are fitted into the rails 9BU-j and 9BD-j. The shielding member 8B-j is biased toward the parent plate 55L (in the direction of arrow L in the frame in FIG. 7) by an elastic body (not shown).

  A drive unit 73 is housed in the housing 51. The drive unit 73 plays a role of adjusting the sound absorption effect and the scattering effect generated by the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) according to the operation of the pedal 66. Device. This drive part 73 moves shielding member 8A-n (n = 1-4) and 8B-j (j = 1-5) according to operation of the pedal 66, and thereby shielding member 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) to adjust the shielding amount of the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5). Here, the shielding amount refers to the shielding members 8A-n (n = 1 to 4) and 8B-j (j in the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5). = 1 to 5) means the area of the region shielded.

  More specifically, when the operation of depressing the pedal 66 is performed, the driving unit 73 attaches the shielding members 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) to the parent plate 55R. Pull to the side (arrow R direction in the frame of FIG. 7). Thereby, shielding member 8A-n (n = 1-4) and 8B-j (j = 1-5) resist opening force 7A-n (n = 1-4) and urging | biasing force of an elastic body, and 7B-j (j = 1 to 5) is moved from the position of the main plate 55R (in the direction of arrow R in the frame of FIG. 7) to the openings 7A-n (n = 1 to 4) and 7B-j ( The opening area which is the area of the portion not covered with the shielding members 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) in j = 1 to 5) is increased.

  Moreover, the drive part 73 weakens the force which pulls shielding member 8A-n (n = 1-4) and 8B-j (j = 1-5), when operation which cancels | releases depression of the pedal 66 is performed. Thereby, the shielding members 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) move to the side of the parent plate 55L (in the direction of arrow L in the frame of FIG. 7) (that is, open) Parts 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5)), openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5) ) The opening area becomes smaller.

  The above is the details of the configuration of the present embodiment. In the present embodiment, the upright piano 50 itself that is a keyboard instrument has the acoustic structures 5A and 5B. Each of the pipes 6A-n (n = 1 to 4) of the acoustic structure 5A and the pipes 6B-j (j = 1 to 5) of the acoustic structure 5B generates a sound absorption effect and a scattering effect. In this embodiment, the pipe 6A-n (n = 1 to 4) and the pipe 6B-j (j = 1 to 5) have the same length, and the pipe 6A-n (n = 1 to 4). ) And the positions of the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5) on the side surface BW ′ of the pipe 6B-j (j = 1 to 5) are different for each pipe. . According to the present embodiment, the sound absorption effect and the scattering effect can be generated in a wide band over the entire sound range of the upright piano 50. Therefore, according to the present embodiment, the coloration generated in the upright piano 50 can be suppressed in a wide band. Moreover, the upright piano 50 which is this embodiment is the shielding member 8A-n (n which shields the pedal 66 and opening part 7A-n (n = 1-4) and 7B-j (j = 1-5). = 1 to 4) and 8B-j (j = 1 to 5), and openings by shielding members 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) according to the operation of the pedal 66 And a drive unit 73 that adjusts the shielding amount of the units 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5). Therefore, according to the present embodiment, the sound absorption effect and the scattering effect can be adjusted through the operation of the pedal 66.

<Third Embodiment>
FIG. 8 is a perspective view of the cajon 9 according to the third embodiment of the present invention. 9 is a cross-sectional view taken along line AA ′ of FIG. The casing 90 of the cajon 9 has a hollow cubic shape. The housing 90 has six plates 91, 92, 93, 94, 95, 96 having the same dimensions. The plates 91 and 92 are opposed to each other in the vertical direction. The plates 93 and 94 are opposed in the front-rear direction. The plates 95 and 96 are opposed in the left-right direction. An open sound port 97 is provided at the center of the plate 94 in the housing 90. Further, the plate 93 in the housing 90 constitutes a striking surface that is struck by the palm of the performer. Between the plate 91 and the plate 92 in the housing 90, strings 98, 99, and 100 as sounding bodies are stretched. On the surface of the plate 96 facing the strings 98, 99 and 100, there is an acoustic structure 120 integrated with the plate 96. The acoustic structure 120 includes a plurality of pipes 101-u (u = 1 to 6) in which openings 102-u (u = 1 to 6) are provided on the side surfaces surrounding the internal cavities. is there.

  Each pipe 101-u (u = 1 to 6) of the acoustic structure 120 has side surfaces LW "and RW" facing in the left-right direction, side surfaces FW "and BW" facing in the front-rear direction, and side surfaces UW facing in the up-down direction. "And DW". Here, in FIG. 8 and FIG. 9, for convenience, the side surfaces FW ″, BW ″, UW ″, DW ″, LW ″, RW ″ of each of the pipes 101-2 to 102-6 except the pipe 101-1. The illustration of the reference numeral is omitted. The lengths of the pipes 101-u (u = 1 to 6) are the same. The pipes 101-u (u = 1 to 6) are arranged in the front-rear direction with the side surfaces UW ″ and DW ″ aligned. The side face LW ″ of the pipe 101-u (u = 1 to 6) is joined to the face of the plate 96 facing the strings 98, 99, 100. The opening of each pipe 101-u of the acoustic structure 120 102-u is provided on the side surface RW ″ of the pipe 101-u. The position of the opening 102-u (u = 1 to 6) in the length direction of the pipe 101-u (u = 1 to 6) is different for each pipe.

  The above is the details of the configuration of the present embodiment. In the present embodiment, the cajon 9 that is a musical instrument itself has the acoustic structure 120. Each of the pipes 101-u (u = 1 to 6) of the acoustic structure 120 generates a sound absorption effect and a scattering effect. In the present embodiment, the pipes 101-u (u = 1 to 6) have the same length, and the opening 102-u (on the side surface BW ″ of the pipe 101-u (u = 1 to 6). The position of u = 1 to 6) is different for each pipe, so that the present embodiment can provide the same effects as those of the first and second embodiments.

  Although the first to third embodiments of the present invention have been described above, the present invention may have other embodiments. For example, it is as follows.

(1) A shielding member that shields the opening 3-m (m = 1 to 10) of the pipe 2-m (m = 1 to 10) of the grand piano 10 of the first embodiment, and an opening by the shielding member. It is good also as a structure which comprises the drive part which adjusts the shielding amount of the part 3-m (m = 1-10).

(2) In the said 1st thru | or 3rd embodiment, you may open | release the one or both edge part of all or one part of the pipe which comprises acoustic structure 1,5A, 5B, 120.

(3) In the second embodiment, the pipes 6A-n (n = 1 to 4) of the acoustic structure 5A and the pipes 6B-j (j = 1 to 6) of the acoustic structure 5B extend in the left-right direction. It was. However, the pipes 6A-n (n = 1 to 4) and the pipes 6B-j (j = 1 to 6) may extend in the vertical direction.

(4) In the said 1st Embodiment, the acoustic structure 1 was joined on the surface which faced the space in the housing | casing 11 in the large roof 15 of the piano 10. FIG. However, the large roof 15 may be formed of a wide and thick plate, and the acoustic structure 1 may be embedded in the large roof 15.

(5) In the second embodiment, the acoustic structure 5A is joined to the surface of the upper front plate 52 of the piano 50 facing the soundboard 72, and the acoustic structure 5B is joined to the lower front plate 53 of the piano 50. It was joined on the surface facing the soundboard 72. However, the upper front plate 52 and the lower front plate 53 may be formed of a wide and thick plate, and the acoustic structures 5A and 5B may be embedded in each of the upper front plate 52 and the lower front plate 53. Further, the acoustic structures 5A and 5B may be integrated with the rear plate 54 in the housing 51.

(6) The first embodiment is an application of the present invention to a grand piano, the second embodiment is an application of the present invention to an upright piano, and the third embodiment is an application of the present invention. The invention was applied to Cajon. However, the acoustic structure may be housed in a case of a stringed instrument such as a guitar or a violin.

(7) In the third embodiment, a bell that is a type of sounding body different from the strings 98, 99, 100 may be provided in the housing 90.

(8) In the second embodiment, when the operation of depressing the pedal 66 is performed, the driving unit 73 has the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5). An operation was performed to increase the opening area. However, when the driver 73 depresses the pedal 66, the shielding members 8A-n (n = 1 to 4) and 8B-j (j = 1 to 5) are opened to the openings 7A-n (n = 1 to 4). And 7B-j (j = 1-5), and when the pedal 66 is fully depressed, the openings 7A-n (n = 1-4) and 7B-j (j = 1-5) are all blocked. You may make it come off.

(9) In the second embodiment, the driving unit 73 expands or contracts the opening area of the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5) to reduce the pipe 6A. The mode of generation of the sound absorption effect and the scattering effect by -n (n = 1 to 4) and 6B-j (j = 1 to 5) was adjusted. However, the driving unit 73 changes the pipe length of the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) or the position of the pipe in the casing 51 by changing the pipe position. You may adjust the aspect of the sound-absorption effect and scattering effect by -n (n = 1-4) and 6B-j (j = 1-5).

  For example, when the pedal 66 serving as an operator is depressed, the driving unit 73 positions the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) in the casing 51 on the right side. The sound source is moved by a slight distance and the position of the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) is restored when the pedal 66 is released. The positional relationship between the position and the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5) may be changed to adjust the generation of the sound absorption effect and the scattering effect.

  Or the following aspects are also considered. First, in FIG. 6, each pipe 6A-n (n = 1-4) and 6B-j (j = 1-5) are made the structure which can adjust length. Specifically, as the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5), the open end and the closed end are arranged from the open end side of the thick pipe having the open end and the closed end. A pipe pair having a configuration in which an open end of a thin pipe is inserted is used. Further, an actuator for moving the position of the closed end of the thin pipe is provided in the thick pipe of each pipe pair. Further, in this aspect, the drive unit 73 includes the pipes 6 </ b> A-n (n = 1 to 4) and 6 </ b> B-j (j = 1 to 5) in the housing when the pedal 66 as an operator is depressed. The thin pipe is accommodated in the thick pipe (ie, the length of the pipe pair as a whole is shortened), and when the pedal 66 is released, the thin pipe is protruded from the thick pipe (ie, the pipe length of the pipe pair as a whole is reduced). Lengthen). According to this aspect, the lengths of the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) are changed according to the operation of the pedal 66, and the sound absorption effect and the scattering effect are generated. The frequency to be changed can be changed.

  Or the following aspects are also considered. For example, as the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5), pipes that can transform a rectangular parallelepiped cross-sectional shape into a parallelogram shape are used. Further, in this aspect, the drive unit 73 changes the rectangular parallelepiped cross section to a parallelogram cross section so that the cross-sectional area of the pipe in the housing becomes small when the pedal 66 as the operation element is stepped on, and the pedal 66 Return to the original position when stepping on is released. Here, when the cross-sectional areas of the pipes 6A-n (n = 1 to 4) and 6B-j (j = 1 to 5) are reduced, the sound absorption performance of each pipe tends to be reduced. Therefore, according to this aspect, it is possible to easily obtain the same effect as expanding or contracting the opening area of the openings 7A-n (n = 1 to 4) and 7B-j (j = 1 to 5). Can do.

(10) In the second embodiment, the opening area adjustment pedal 66 is replaced with another type of operation element such as a knob or a switch, and the drive unit 73 performs pipe 6A-n (n = 1) in accordance with the operation of the operation element. -4) and 6B-j (j = 1 to 5) may be adjusted in terms of the sound absorption effect and the scattering effect.

(11) In the cajon 9 of the third embodiment, the operation elements such as pedals, knobs, and switches, and the opening 102-u (u = 1) of the pipe 101-u (u = 1 to 6) of the acoustic structure 120. To 6), and a drive unit that adjusts the shielding amount of the opening 102-u (u = 1 to 6) by the shielding member according to the operation of the operator.

(12) In each of the embodiments described above, all the opening portions of each pipe face the inside of the housing, but some of the opening portions of the pipes may open toward the outside of the housing. Specifically, an opening is provided at a corresponding position of the casing, and the opening of the pipe is exposed through the opening of the casing. By doing in this way, suitable control of coloration becomes possible. Moreover, the acoustic characteristics of the room can be adjusted by placing the piano or cajon having such a configuration in the room.

DESCRIPTION OF SYMBOLS 1,5 ... Acoustic structure, 2,6 ... Pipe, 3,7 ... Opening part, 11,51 ... Housing, 12,58 ... Shelf board, 13 ... Side board, 14,59 ... Frontal board, 15 ... Large roof , 16 ... Rush bar, 17 ... Front roof, 18 ... Pedal pedestal, 19 ... Pedal box, 20L, 20R, 20C ... Leg, 21 ... Casters, 22, 23, 24 ... Pedal, 25, 63 ... Key, 52 ... upper front plate, 53 ... lower front plate, 54 ... rear plate, 55L, 55R ... master plate, 60L, 60R ... brace, 61L, 61R ... wife base, 62L, 62R ... pedestal.

Claims (5)

A housing having a front plate ; and a sounding body provided in the housing;
An acoustic structure housed in the housing and integrated with the front plate, the acoustic structure having a plurality of pipes with openings provided on side surfaces surrounding the respective internal cavities. And
The acoustic structure is installed with the side surface provided with the opening facing the housing. An operator,
The musical instrument according to claim 1, further comprising: a drive unit that adjusts a mode of generation of a sound absorption effect and a scattering effect by the pipe according to an operation of the operation element. Comprising a shielding member for shielding the opening,
The musical instrument according to claim 2, wherein the driving unit adjusts a shielding amount of the opening portion by the shielding member in accordance with an operation of the operation element. A shelf plate, a curved side plate fixed along an edge of the shelf plate, a front ridge constructed between parallel facing wall surfaces of the curved side plate, and a rear side of the front ridge on the wall surface of the curved side plate A housing having a large roof,
A string stretched in the housing;
An action mechanism for converting a key pressing force into a string striking force;
An acoustic structure integrated with the large roof, the acoustic structure having a plurality of pipes each having an opening provided on a side surface surrounding each internal cavity; and
The grand structure according to claim 1, wherein the acoustic structure is installed with a side surface provided with the opening portion facing the housing. An upper front plate and a lower front plate arranged in the vertical direction at intervals, a rear plate facing the upper front plate and the lower front plate, and two master plates sandwiching these three plates from the left and right directions A housing having
A string stretched in the housing;
An action mechanism for converting a key pressing force into a string striking force;
An acoustic structure integrated with at least one of the upper front plate and the lower front plate , wherein the acoustic structure has a plurality of pipes with openings provided on side surfaces surrounding the respective internal cavities; Have
The upright piano, wherein the acoustic structure is installed with a side surface provided with the opening facing the housing.

Images