Patent Grant
7501570
The present invention relates generally to key detection structures for wind instruments, and more particularly to an improved key detection structure for a wind instrument which allows detector units, for detecting states etc. of corresponding keys, to be readily attached and detached to and from the wind instrument.
There have been known key detection structures of a type which reproduces electronic tones by detecting operation of keys on a wind instrument, and examples of such a type of key detection structure are disclosed in Japanese Utility Model Application Laid-open Publication No. HEI-4-89999 and Japanese Patent Application Laid-open Publication No. HEI-8-305362. According to the disclosure of the No. HEI-4-89999 and No. HEI-8-305362 publications, a module including switches and hall elements is previously incorporated in a tubular body and keys forming the wind instrument. Namely, the wind musical instruments disclosed in these publications differ in construction and tone-generating form from the so-called acoustic type wind musical instruments; namely, if the module is removed, the disclosed wind musical instruments can no longer generate any performance tone. I recent years, however, there has been a demand that the above-mentioned module be detachably attached to an acoustic musical instrument so that two different kinds of tones, i.e. electronic reproduced tone and acoustic performance tone generated by the musical instrument itself, can be used appropriately as needed.
Where an acoustic-type wind musical instrument is to be constructed to detect operation of keys in order to reproduce electronic tones as well, use of structure (1) and structure (2) outlined below are conceivable.
According to structure (1), a magnetic member is fixed to a position adjacent to the reverse or back surface of a key, and a hall element is mounted in the tubular body. As the key opens or closes a tone hole, variation in magnetic field responsive to the displacement of the magnetic member is detected by the corresponding hall element, so that an electrical signal corresponding to the key's opening or closing movement is output.
Structure (2) is different from structure (1) in terms of attached positions of the magnetic member and hall element. Namely, according to structure (2), the magnetic member is supported outside the corresponding key via an arm, while the hall element is attached to the outer surface of the tubular body.
However, structure (1) above would present the inconvenience that operation for attaching the magnetic member to the position adjacent to the back surface of the key requires is very cumbersome and requires a great amount of time. The inconvenience is due to the fact that, during the attaching operation, it is essential to attach the magnetic member after detaching or disassembling the key from the tubular body and insert the magnetic member into a narrow space between the tubular body and the key. Further, because the magnetic member is attached to the position adjacent to the back surface of the key, the structure would be subjected to the constraint that the tone hole can not be opened and closed by the key unless the magnetic member is sized so to be received in the tone hole.
Further, structure (2) above would present the inconveniences that operation for attaching the hall element to the outer peripheral surface of the tubular body and a construction for supporting the magnetic member via the arm tend to be very complicated, and that operation for disassembling the key and the like at the time of repair or care of the wind instrument tends to be cumbersome and difficult. In particular, because the outer peripheral surface of the tubular body is a curved surface, the attached state of the hall element tends to be unstable.
In view of the foregoing, it is an object of the present invention to provide a key detection structure for a wind instrument which is simple in construction and allows each detector unit to be attached and detached with ease.
It is another object of the present invention to provide a key detection structure for a wind instrument which can be attached to an acoustic-type musical instrument.
In order to accomplish the above-mentioned objects, the present invention provides an improved key detection structure for detecting opening/closing states or positions of keys in a wind instrument including a tubular body having a plurality of tone holes formed therein and a plurality of the keys pivotably mounted on the tubular body to open/close the tone holes, which comprises: a plurality of detector units provided within the tubular body in corresponding relation to the plurality of the keys, each of the detector units being generally opposed to the back surface of the corresponding key to detect a relative distance to the back surface and output an electrical signal corresponding to the relative distance; and a retaining member accommodated in the tubular body and positioning and retaining each of the detector units in such a manner that that the keys and tubular body and the individual detector units are kept in non-contacting relation to each other.
According to the present invention, the individual detector units can be attached and detached with ease and promptly by just inserting and taking the retaining member into and out of the tubular body. With the detector units kept in non-contacting relation to the corresponding keys, the present invention can eliminate the needs for attaching the detector units with respect to the individual keys and placing the detector units in the tone holes, with the result that not only the key detection structure can be simplified in construction but also constraints or limitations in design, such as a size, of the detector units can be significantly lessened. In addition, the present invention can save labor in diassembling the keys from the tubular body and also reduce workload necessary for care and repair of the wind instrument.
Preferably, the retaining member includes an axially-extending member extending along the axis of the tubular body, and a plurality of contact portions provided on the axially-extending member and pressed against the inner peripheral surface of the tubular body. With the contact portions pressed against the inner peripheral surface of the tubular body, the retaining member can be supported by the inner peripheral surface of the tubular body in such a manner that it is freely attachable and detachable to and from the tubular body, even where the inner surface of the tubular body is a smooth surface as in a so-called acoustic-type wind instrument. Further, the retaining member can be moved, by application of an external force, to allow the contact portions to be displaced little by little within the tubular body, so that fine adjustment of the installed position of the detector units can be made with ease. Furthermore, with the detector units provided on the single axially-extending member at positions corresponding to the keys, the present invention can even further expedite the installation operation.
Preferably, the axially-extending member has at least two retaining surfaces oriented in different directions, and these retaining surfaces are constructed to retain thereon the detector units. Thus, even where the wind instrument has keys oriented in two different directions, e.g. in an upward direction and obliquely-downward direction as viewed from a human player of the instrument, the detector units corresponding to the differently oriented keys can be readily fixed in predetermined positions via the single axially-extending member.
Preferably, each of the detector units comprises a photo reflector. Thus, in the present invention, a distance between the photo reflector and the key can be detected accurately, so that the opening/closing state of the key can be detected with a high accuracy.
Preferably, a reflector member or refractor member is provided between each of the detector units and the key corresponding to the detector unit so that light emitted by the photo reflector can be reflected or refracted by the reflector member or refractor member. Thus, where the light emitted by the photo reflector is reflected or refracted via the reflector or refractor member, the light emitted by the photo reflector can be appropriately directed to fall on the back surface of the key irrespective of the orientation of the photo reflector, with the result that the present invention can reduce the positional constraints of the detector units and thereby enhance the design freedom.
The following will describe embodiments of the present invention, but it should be appreciated that the present invention is not limited to the described embodiments and various modifications of the invention are possible without departing from the basic principles. The scope of the present invention is therefore to be determined solely by the appended claims.
For better understanding of the objects and other features of the present invention, its preferred embodiments will be described hereinbelow in greater detail with reference to the accompanying drawings, in which:
The tubular body 11 comprises a head joint (or head section) 14 having an embouchure plate 14A, a main tube (or main body) 15 connectable to one end (right end in
Each of the keys 12 is formed into a dish shape and disposed adjacent to the opening portion 18A of one of the tone holes 18. Each of the keys 12 is pivotably supported via an arm 20 on the main tube 15 or foot joint 16 to open and close the tone hole 18 (see
Each of the detector units 22, which are disposed in positionally-corresponding relation to the keys 12, is capable of detecting a relative distance to the back surface of the corresponding key 12 to output an electrical signal corresponding to the distance. With such a detector unit 22, an opened/closed state of the tone hole 18, openable and closable by the key 12, can be detected.
More specifically, as shown in
As shown in
The axially-extending member 38 is in the form of a plate having a V sectional shape, and it has a length slightly smaller than a total or combined length of the main tube 15 and foot joint 16. The axially-extending member 38 has a first retaining surface 38A oriented toward the opening portion 18A of the tone hole 18 that is oriented in the upward direction of
Each of the contact portions 39 has a mounting surface 39B located adjacent to (or on the same side as) the front surface of the printed circuit board 41, and a curved surface 39A shaped to extend along the inner peripheral surface of the tubular body 11. Each of the contact portions 39 is formed of a resilient material, such as foamed rubber. Thus, as the retaining member 22 is inserted into the tubular body 11, the contact portions 39 are resiliently compressed to be pressed contact with the inner peripheral surface of the tubular body 11. Thus, the retaining member 23 can be prevented from moving within the tubular body 11 unless an intentional external source is applied to the retaining member 23, and the axially-extending member 38 and the tubular body 11 can be kept in non-contacting relation to each other. Also, the retaining member 23 can appropriately retain the individual detector units 22 at the predetermined positions, corresponding to the keys 12, such that the keys 12 and tubular body 11 and the individual detector units 22 are kept in non-contacting relation to each other.
Although not specifically shown, a pressure sensor is provided on or near the head joint 14 for detecting a blowing pressure to output an electrical signal corresponding to the detected pressure. The electrical signals output from the pressure sensor and detector units 22 are controlled via the predetermined control section and then supplied to a reproduction device (not shown), including an amplifier, speaker etc., for generation of reproduced tones of predetermined pitches.
In mounting or attaching the detector units 22 to the tubular body 11, the head joint 14 and the main tube 15 are first detached from each other, and then the retaining member 23, having the detector units 22 previously retained thereon, is inserted into the interior of the main tube 15 and foot joint 16. Thus, the retaining member 23 is snugly received in the main tube 15 and foot joint 16, and the individual contact portions 39 are resiliently pressed against the inner peripheral surface of the main tube 15 and foot joint 16. At that time, the first retaining surface 38A is oriented in the upward direction of
Note that applying an intentional external source to the retaining member 23 under such conditions can rotate or displace the retaining member 23 within the tubular body 11 so that the position of each of the detector units 22 can be adjusted finely.
Further, in order to detach or dismount the detector units 22 from the tubular body 11, it is only necessary that the retaining member 23 be pulled out of the main tube 15 and foot joint 16 after the head joint 14 and the main tube 15 are detached from each other.
When a music performance is to be executed by generating electric reproduced tones using the wind instrument 10, the tone holes 18 are opened and closed by a human player manipulating the keys 12 with his or her finger tips, as is the case with a conventional flute. During that time, the detector units 22 detect relative distances to the back surfaces of the corresponding keys 12, so that electrical signals corresponding to the relative distances are supplied from the detector units 22 to the above-mentioned control section. The control section in turn detects opening/closing states of the keys 12 on the basis of the supplied electrical signals and then outputs the detected states to the reproduction device as predetermined tone pitch information, in response to which the reproduction device reproduces electric tones.
In the above-described manner, the instant embodiment not only can detect the opening/closing states of the keys 12 but also allows the detector units 22 to be attached and detached to and from the neighborhoods of the keys 12 with utmost ease and within a very short time, with the simplified construction. Thus, the single or same wind instrument 10 can selectively sound both electric reproduced tones based on the detection via the detector units 22 and acoustic tones based on air vibration by the instrument itself. Namely, the same wind instrument can be played both as an electronic musical instrument and as an acoustic musical instrument, with the result that the usability of the instrument can be dramatically enhanced.
Whereas the present invention has been shown and described in relation to the particular embodiment, the explanations having been made above are just for illustrative purposes and never intended to limit the present invention, and the shapes, positions, directions and other detailed constructions described above may be modified variously without departing from the basic technical idea and objects of the present invention.
For example, the axially-extending member 38 may be modified variously, as exemplified in
As another modification of the axially-extending member 38, the printed circuit boards 41 provided on the first and second retaining surfaces 38A and 38B may be integrally formed into one piece; in this case, the integrally-formed printed circuit board 41 is mounted on the retaining surfaces 38A and 38B by being bent along the retaining surfaces 38A and 38B.
Further, as illustratively shown in
Furthermore, the axially-extending member 38 may be formed to have an even greater number of the retaining surfaces; such an increased number of the retaining surfaces allow the axially-extending member 38 to be more readily applied to a wind instrument 10 whose tone holes 18 are oriented in various different directions.
Furthermore, whereas the embodiment has been described in relation to the case where the wind instrument 10 is a flute, the wind instrument 10, to which the present invention is applied, may be of any other type, such as a soprano saxophone, bass flute, alto flute or piccolo, and the shape of the retaining member 23 and the positions of the detector units 22 may be modified in accordance with the shape of the tubular body 11 of the wind instrument 10 to which the present invention is applied.
| Number | Date | Country | Kind |
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| 2005-180332 | Jun 2005 | JP | national |
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