1. Field of the Invention
The present invention relates to a percussion instrument having sounding members each adapted to generate a musical tone when struck.
2. Description of the Related Art
A keyboard-type tone plate percussion instrument has been known, which includes a plurality of keys, hammer actions respectively corresponding to these keys, and tone plates (sounding members) each adapted to be struck by a corresponding hammer action (see, for example, Japanese Utility Model Laid-open Publication No. 05-081895). With this percussion instrument, when any of the keys is depressed by a player, a corresponding hammer action strikes a tone plate, whereby the tone plate vibrates to generate a musical tone of a tone pitch proper to the tone plate.
In the keyboard-type tone plate percussion instrument disclosed in Japanese Utility Model Laid-open Publication No. 05-081895, there are horizontally disposed strip-shaped tone plates to correspond to respective ones of the keys, and these tone plates have different lengths or widths from one another and are supported for vibration by pins. Such a structure in which tone plates are supported using pins has been known from a long time ago. This structure is capable of sustaining tone plates in vibration to thereby generate musical tones with a satisfactory quality. However, the construction in which tone plates are supported by pins requires the pins which correspond in number to the tone plates, resulting in an increased number of component parts, thus lowering the workability at the time of assembly and maintenance. Therefore, a structure has been demanded, which is excellent in workability at the time of assembly and maintenance and capable of sustaining tone plates in vibration to generate musical tones with a high quality.
The present invention provides a percussion instrument which is excellent in workability at the time of assembly and maintenance and capable of sustaining sounding members in vibration to thereby generate musical tones with a high quality.
According to a first aspect of this invention, there is provided a percussion instrument comprising a plurality of sounding members each formed into a column shape having side surfaces thereof facing each other and formed with a through hole extending therethrough from one side surface thereof to another side surface thereof, each of the sounding members being adapted to generate, when struck, amusical tone of a tone pitch proper to the sounding member, a supporting cord adapted to be inserted through the through holes formed in the sounding members and having a core string therein, the supporting cord being provided at its surface with a nonwoven fabric comprised of intertwined fibers, and a plurality of fasteners adapted to support portions of the supporting cord located outside the through holes of the sounding members.
In this invention, the supporting cord can include a cord-shaped nonwoven fabric comprised of intertwined fibers spirally wound around the core string.
The supporting cord can include a plurality of cord-shaped nonwoven fabrics each comprised of intertwining fibers, the nonwoven fabrics being twined together and covering the core string.
The supporting cord can have an approximately circular shape in cross section in a direction perpendicular to a longitudinal direction of the supporting cord.
A ratio between a diameter of the supporting cord and an inner diameter of the through hole can have a predetermined value.
According to a second aspect of this invention, there is provided a keyboard-type percussion instrument comprising a plurality of sounding members each formed into a column shape having side surfaces thereof facing each other and formed with a through hole extending therethrough from one side surface thereof to another side surface thereof, each of the sounding members being adapted to generate, when struck, a musical tone of a tone pitch proper to the sounding member, a supporting cord adapted to be inserted through the through holes formed in the sounding members and having a core string therein, the supporting cord being provided at its surface with a nonwoven fabric comprised of intertwined fibers, a plurality of fasteners adapted to support portions of the supporting cord located outside the through holes of the sounding members, a plurality of keys disposed to correspond to respective ones of the plurality of sounding members, action mechanisms disposed to correspond to respective ones of the plurality of keys, each of the action mechanisms being adapted to strike one of the sounding members in response to a motion of a corresponding one of the keys, and a resonance box adapted to cause musical tones generated by respective ones of the sounding members to resonate therein.
The percussion instrument of this invention is excellent in workability at the time of assembly and maintenance thereof and capable of sustaining sounding members in vibration to generate musical tones with a high quality.
Further features of the present invention will become apparent from the following description of an exemplary embodiment with reference to the attached drawings.
The present invention will now be described in detail below with reference to the drawings showing a preferred embodiment thereof.
First, an explanation will be given of the outline of the keyboard-type percussion instrument 10. This percussion instrument 10 is adapted to cause each of metallic sounding members to vibrate to generate a musical tone when the sounding member is struck. As shown in
Next, an explanation will be given of the internal construction of the keyboard-type percussion instrument 10.
First, an explanation will be given of various parts disposed below the tone generator unit UNT. As shown in
On the key frame 15, action brackets 22 for supporting the action mechanisms 20 are disposed to correspond to respective ones of the keys. The action mechanisms 20 are the same in construction as those of a grand piano which strike strings provided therein. Each action mechanism 20 includes a hammer shank 23 adapted to be pivotable clockwise or counterclockwise around a fulcrum P1 in accordance with movement of a corresponding key of the keyboard KB, and a hammer felt 24 provided at a tip end of the hammer shank 23 for striking the corresponding sounding member 30.
On the rear side of the keyboard-type percussion instrument 10, pivotal members 64 are disposed above the keybed 14 to correspond to respective ones of the keys of the keyboard KB. Damper wires 25 having damper felts 26 are attached to the pivotal members 64 to be pivotable clockwise or counterclockwise around fulcrums P2 shown in
On the rear side of the percussion instrument 10, a tappet member 65 is disposed below the pivotal members 64 in contact with a pedal coupling rod 13 coupled to the damper pedal 12 and disposed for vertical motion in unison with the pedal coupling rod 13. Since the tappet member 65 is in contact with all the pivotal members 64 disposed to correspond to respective ones of the keys, the tappet member 65 causes all the pivotal members 64 to be pivoted upon a vertical motion of the pedal coupling rod 13.
According to the above construction, when any of the keys of the keyboard KB is depressed by the player, a rear end portion of the depressed key is moved upward and the pivotal member 64 corresponding thereto is pivoted clockwise in
Subsequently, when the player's finger is taken off the depressed key, the rear end portion of the key is moved downward, and the action mechanism 20 causes the hammer shank 23 to be pivoted clockwise, so that the hammer felt 24 is moved away from the sounding member 30. With the motion of the rear end portion of the key, the pivotal member 64 is pivoted counterclockwise. When the pivotal member 64 is pivoted counterclockwise, the damper wire 25 is moved downward and the damper felt 26 is made in contact with the sounding member 30, thus suppressing the vibration of the sounding member 30.
When the damper pedal 12 is stepped on, the pedal coupling rod 13 is moved upward, and the tappet member 65 causes all the pivotal members 64 to be pivoted clockwise. With the clockwise pivotal motion of the pivotal members 64 around the fulcrum P2, the damper wires 25 are moved and all the damper felts 26 are spaced apart from the sounding members 30. When the damper pedal 12 is stepped on and the pivotal members 64 are pivoted clockwise, the rear end portions of the keys are made out of contact with the pivotal members 64. Thus, even if the player's finger is taken off a depressed key, the vibration of the corresponding sounding member 30 is not suppressed by the damper felt 26.
Next, an explanation will be given of the construction of the tone generator unit UNT.
The sounding members 30 are made of aluminum. The material of the sounding members 30 is not limited to aluminum but may be an aluminum alloy, steel, or some other metal. The sounding members 30 corresponding to respective ones of the keys are different in length, width, and shape from one another. When struck by hammer felts 24, the sounding members 30 vibrate in many different forms to generate musical tones of tone pitches proper to respective ones of the sounding members.
Specifically, as shown in
As shown in
Next, an explanation will be given of the construction of the resonance box 50. The resonance box 50 is formed into a box shape having an open lower surface, and has its front common wall 51 forming a front surface thereof, a rear common wall 52 forming a rear surface thereof, side walls 59A, 59B forming left and right side surfaces thereof, and lid members 56, 57 and 58 closing an upper surface thereof. As shown in
Each of the front and rear common walls 51, 52 of the resonance box 50 is comprised of a plate-like member having two rectangular portions thereof corresponding to the low- and high-pitch range portions 50A, 50C of the resonance box 50 and a trapezoidal portion thereof corresponding to the mid-pitch range portion 50B of the resonance box 50, as shown in
As shown in
In the high-pitch range portion 50C of the resonance box 50, the resonance chamber RM3 is defined by a partition plate 53 disposed between the mid- and high-pitch range portions 50B, 50C, the front and rear common walls 51, 52, and the lid member 58 closing an upper part of the high-pitch range portion 50C. As shown in
In the mid-pitch range portion 50B, a space defined by each adjacent two of the partition plates 53 is divided by an inclined plate 55, which is comprised of a flat plate. The inclined plate 55 is connected to central portions of the two partition plates 53 in the forward-to-backward direction and extends obliquely as seen from above, thereby defining two resonance chambers RM2 in the space defined by the each adjacent two of the partition plates 53. In the mid-pitch range portion 50B, a lid member 57 for each of spaces defined by the partition members 53 is connected to upper portions of the partition plates 53 and the front and rear common walls 51, 52 so as to close an upper part of the space.
In
In this embodiment, each of the resonance chambers corresponding to respective ones of the sounding members 30 has its width nearly two times the width of the corresponding sounding member 30. Thus, it is ensured that a resonance chamber having a broad width is provided for each sounding member 30, making it possible to realize satisfactory resonance. In addition, only the width equal to the total width of two sounding members 30 is required for the provision of two resonance chambers, while ensuring that each of the resonance chambers for respective sounding members 30 can have a broad width. Thus, the entire width of the resonance box 50 in the left-to-right direction can be suppressed from increasing, making it possible to arrange the sounding members 30 in a one-stage structure.
Also in the low-pitch range portion 50A of the resonance box 50, a space defined between each adjacent two partition plates 53 is divided by an inclined plate 54, as in the case of the mid-pitch range portion 50B. The inclined plate 54, which is formed by a flat plate, extends obliquely relative to the partition plates 53 as seen from above, and is connected to central portions of these two partition plates 53, whereby two resonance chambers RM1 are defined in the space between each adjacent two partition plates 53. In the low-pitch range portion 50A in which the distance between each adjacent two partition plates 53 differs from that in the mid-pitch range portion 50B, an inclination angle of the inclined plate 54 relative to the two partition plates 53 differs from that of the inclined plate 55 relative to the partition plates 53. In the low-pitch range portion 50A of the resonance box 50, port-forming members 60 are provided on the front and rear common wall 51, 52 sides in a lower portion of each of resonance chambers RM1. Each port-forming member 60 is formed by a flat plate. Each of the port-forming members 60 on the front side is horizontally connected to the front common wall 51 and each adjacent two partition plates 53 disposed on the both sides of the resonance chamber RM1 concerned. Each of the port-forming members 60 on the rear side is horizontally connected to the rear common wall 52 and two partition plates 53 disposed on the both sides of the resonance chamber RM1.
Each resonance chamber RM1 is provided at its opening portion with a port, which is formed by the two partition plates 53 disposed on the both sides of the resonance chamber RM1, the inclined plate 54, and the port-forming member 60. In a Helmholtz-type resonance box, a musical tone resonating therein has a tone pitch that is generally affected by the length and sectional area of the port as well as the volume of the resonance box. For example, the tone pitch at which a musical tone resonates in the resonance box decreases with the increase in port length and with the decrease in port sectional area even when the volume of the resonance box is kept unchanged. In this embodiment, the port-forming member 60 is formed into a shape that is appropriately determined to adjust the length and sectional area of the port of each resonance chamber RM1 so that a musical tone generated by the corresponding sounding member 30 can satisfactorily resonate in the resonance chamber RM1.
Next, an explanation will be given of the construction in which the sounding members 30 are arranged in a lower part of the resonance box 50.
In mounting the sounding members 30 below the resonance box 50, the sounding members 30 are first brought together using the supporting cord 44. Specifically, the sounding members 30 are first arranged in the order of tone pitch in the left-to-right direction. The sounding member 30 for the lowest pitch tone is arranged on the leftmost side, whereas the sounding member 30 for the highest pitch tone is arranged on the rightmost side.
Next, the supporting cord 44 is inserted from left to right through the front supporting hole 36 of the leftmost sounding member 30. After inserted through the front supporting hole 36 of the leftmost sounding member 30, the cord 44 is inserted through the front supporting hole 36 of the right-hand neighbor of the leftmost sounding member 30. In this way, the supporting cord 44 is sequentially inserted through the front supporting holes 36 of all the sounding members 30 arranged in the order of tone pitch.
After inserted through the front supporting holes 36 of all the sounding members 30, the supporting cord 44 is inserted from right to left through the rear supporting hole 37 of the rightmost sounding member 30. After inserted through the rear supporting hole 37 of the rightmost sounding member 30, the cord 44 is inserted through the rear supporting hole 37 of the left-hand neighbor of the rightmost sounding member 30. The supporting cord 44 is sequentially inserted through the rear supporting holes 37 of all the sounding members 30 arranged in the order of tone pitch.
After inserted through the front and rear supporting holes 36, 37 of all the sounding members 30, the both ends of the supporting cord 44 are tied together. By tying the both ends of the cord 44 together, all the sounding members 30 are brought together in the order of tone pitch.
Next, a plurality of fasteners 40 adapted to retain the supporting cord 44 below the resonance box 50 are mounted to the resonance box 50.
The pin portion 41 of each fastener 40 is pressed into the front or rear common wall 51 or 52 of the resonance box 50. Each fastener 40 is pressed into the front common wall 51 with an opening portion of the groove 42 directed forward, or pressed into the rear common wall 52 with the opening portion of the groove 42 directed rearward. The distance between positions on the front or rear common wall into which pin portions 41 of each adjacent two fasteners 40 are pressed is larger than the width of the sounding member 30. As shown by way of example in
After the fasteners 40 have been pressed into the resonance box 50, the box 50 is turned with its lower surface facing up, and the sounding members 30 tied together by the supporting cord 44 are placed on the opening portion of the resonance box 50. Then, each adjacent sounding members 30 are moved apart to provide a gap therebetween, and the supporting cord 44 visible from between the sounding members 30 is inserted into the groove 42 of each fastener 40 and hung on the cord receiving portion 43 thereof. At that time, the supporting cord 44 is hung on the cord receiving portions 43 of the fasteners 40 such that one sounding member 30 is located between each adjacent two of the fasteners 40. After the supporting cord 44 is hung on the fasteners 40, the resonance box 50 is turned with its opening portion facing down.
When any of the sounding members hung by the supporting cord 44 is struck by the corresponding hammer felt 23, the sounding member 30 vibrates. In the case of the supporting cord 44 made from, e.g., a single nylon string, the vibration of the sounding member 30 rapidly attenuates and produces noise. As a result, a satisfactory musical tone cannot be attained.
On the other hand, in this embodiment, the supporting members 30 are supported by the supporting cord 44 having a suede-like surface. With this cord 44, no noise is generated when any of the sounding member 30 vibrates, and the sounding member 30 is not hindered from vibrating. As a result, a satisfactory musical tone can be attained when any of the sounding members 30 is struck.
In the above, one embodiment of this invention has been described. This invention is not limitative to the above described embodiment and can be embodied in other forms. For example, this invention can be embodied according to a modification of the embodiment, described below.
In the above described embodiment, the supporting holes 36, 37 formed in the sounding member 30 have a diameter of 4 mm, and the supporting cord 44 inserted through the holes 36, 37 has a diameter of 3.5 mm. However, these diameter values are not limitative. The diameter of the holes 36, 37 can have a value other than 4 mm. In the case of using the supporting holes 36, 37 having a diameter of other than 4 mm, the diameter of the supporting cord 44 with which the sounding members 30 are not hindered from vibrating can be determined by experiment.
In the above described embodiment, the supporting cord 44 is comprised of the core string 44A around which the cord 44B is spirally wound, but the construction of the supporting cord 44 is not limited thereto.
For example, as shown in
The core string 44 can be comprised of a hollow cylindrical cord 44B formed by nonwoven fabric comprised of intertwined fibers and a core string 44A disposed in a hollow portion of the cord 44B.
In the above described embodiment, the core string 44A is made of nylon, but the material of the core string 44A is not limited to nylon. As long as having a strength capable of supporting a plurality of sounding members 30 and capable of withstanding the repetitive vibration, the core string 44A can be made of any other high polymer compound, metal, or natural material. The core string 44A can be two or more in number.
In the above described embodiment, there can be used the supporting cord 44 that is formed into any cross-sectional shape with no corners other than a circular shape.
In the above described embodiment, there can be used two supporting cords 44, one of which is inserted through the front supporting holes 36 of the supporting members 30, whereas another of which is inserted through the rear supporting holes 37 thereof. Then, left end portions of these supporting cords 44 are tied together and right end portions of these are tied together, thereby bringing the sounding members 30 together.
The above described construction where the sounding members 30 are supported by the supporting cord 44 can be adopted in some other idiophone, such as glockenspiel, metalophone, or xylophone, in which sounding members are each adapted to generate, when struck, a musical tone of tone pitch proper to each sounding member.
Number | Date | Country | Kind |
---|---|---|---|
2007-003503 | Jan 2007 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
2458193 | Packheiser | Jan 1949 | A |
3443469 | Hiraoka | May 1969 | A |
Number | Date | Country |
---|---|---|
405 35 | Jul 1999 | AT |
20 2005 017 779 | Jan 2006 | DE |
05778 | Dec 1914 | GB |
5-81895 | Mar 1992 | JP |
U H06-008998 | Feb 1994 | JP |
A H09-097075 | Aug 1997 | JP |
2006-51007 | Feb 2006 | JP |
Number | Date | Country | |
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20080168881 A1 | Jul 2008 | US |