This application claims priority to German Patent Application No. DE 10 2010 027 462.3, filed Jul. 17, 2010 and German Patent Application No. DE 10 2011 010 124.1, filed Jan. 31, 2011, which are both hereby incorporated by reference herein in their entireties.
The present invention relates to a piccolo including a cylindrical headjoint with an embouchure, a stopper with an adjustable seal at its free end and a conical body with tone holes
The concert flute or orchestral Boehm flute used by flautists has a conical headjoint and a cylindrical body. With the current state of technology the piccolo, which sounds an octave higher and also belongs to the family of orchestral Boehm flutes, uses one of the following two designs:
The explanation for the different main uses is to be found in human perception of sound.
The timbre is determined by the overtone structure, i.e. its composition and the strengths of the different overtones, and is affected by the geometrical shape of the tube. There is thus a fundamental difference in timbre and overtone structure between so-called cylindrical flutes and so-called conical flutes. Whilst cylindrical instruments can produce the entire overtone series more or less strongly and without any gaps, the overtone structure of conical instruments is somewhat restricted to the odd-numbered partials. The high register of conical instruments thus sounds more pleasant to the human ear and is therefore preferred for classical music.
The conical piccolo flutes differ from the cylindrical piccolo flutes in terms of acoustic. By the conical narrowing the piccolos become a little deeper and must therefore be, compared to the cylindrical piccolo flutes, made somewhat shorter. Accordingly the tone holes must be placed a little higher to the embouchure. The way to find the exact measurements of the shortening or the distances between the embouchure and tone holes, is the empirical or experimentally. Speculative calculations would be too vague here, because it is important to note that the tone holes serve not only as tone holes but also have sound-wave node-building functions especially in the third, and partially also in the second register. There must be found a compromise for tone, response and intonation. This is only possible through experiments and by trying.
Since the establishment of conical Boehm piccolos in the orchestral, 150 years ago, musicians have wanted a conical Boehm piccolo extending to low c (c1) (sounding c2). Thus nearly all prominent flute makers have worked on the problem, though without succeeding in developing an instrument that meets the timbre requirements for an orchestra. These instruments had, by deepening to deep c1, in the first or low register difficulties with the sound and in the third octave problems with the intonation and especially with the response. This explains why piccolos were built not deeper than d1.
Compositions by Benjamin Britten, Engelbert Humperdinck, Gustav Mahler, Ottorino Respighi, Arnold Schoenberg and Giuseppe Verdi call for a piccolo range extending to c1. Particularly in contemporary music the piccolo is assuming an ever more important role as a solo instrument, e.g. in pieces by Franco Donatoni, Brian Ferneyhough, Jan Huylebroeck, Lowell Liebermann and Karlheinz Stockhausen.
However, without changes to the original compositions the current state of technology does not permit performance of such pieces utilising the timbre of the conical piccolo.
Science has not hitherto been in a position to fully explain the acoustic conditions of vibrating air columns enclosed in instrument tubes. It fails when it comes to giving the instrument maker absolute, reliably calculated figures. Thus constructing an instrument with good tuning and a beautiful sound remains a major problem that can only in part be resolved by using the calculated figures as a guideline, and can better be achieved through experiment and by use of empirically gained knowledge.
The totally different considerations regarding conical piccolos extending to low d (d1) and conical piccolos extending to low c (c1) stem from the fact that most of the parameters regarding woodwind instruments and in particular piccolos can not yet been explained. This is in part attributable to the fact that the flautist's anatomy is to a large extent integrated into and involved in creating the notes. The shaping of the lips, the embouchure and many other factors all play a role, and these considerations cannot easily be registered physically and mathematically. The factors and functions affecting the calculation are major and complex, and their influence has not yet been precisely grasped, thus no usable mathematical solutions are known to date. The conical piccolo going down to c1 does not just represent an extension of the model going down to d1, but is an instrument whose entire construction must be developed using a completely new hole-setting scheme.
On the current state there are no scientific findings on which to base a method of calculation for establishing a hole-setting scheme for conical piccolos. The hole-setting scheme represents more than a known physico-mathematical relationship. There are no concrete solutions to be found in the literature. Proposals alone, as stated in the following literature, are not yet the solution to the problem. A piccolo constructed in accordance with such a proposal could not be used as a concert piccolo, and would at most be feasible as a mass-produced article, e.g. for educational purposes.
The known methods of calculation for establishing a tone-hole arrangement for a wind instrument or flute are laid down in scientific treatises, viz Otto Steinkopfs ‘Zur Akustik der Blasinstrumente’ [On the acoustics of wind instruments] (Celle 1983), C. N. Nederveen's ‘Acoustical aspects of woodwind instruments’ (Amsterdam 1969) and A. H. Benade's ‘On Woodwind Instrument Bores in Journal of the Acoustical Society of America’, Vol. 31, No. 2, 18.11.1957. As regards the above statements, Steinkopf states on p 26 of the above book in the chapter ‘The arrangement of the tone holes (Boehm flute)’: “Totally reliable figures, however, are hardly to be expected in this context, thus one cannot entirely dispense with empirically gained knowledge.”
The evidence for this can also be seen in the fact that the global market has not yet witnessed a usable conical piccolo extending to low c (c1) and with only one c2 hole. Instrument makers have long been seeking a resolution to this problem, and this invention forms the basis for such a resolution.
A further problem is that despite the fact that in 1939 international concert pitch was set at a1=440 Hz in London, it has not been uniformly defined for all countries, thus different piccolos are still being built.
An aspect of the present invention is to provide a piccolo that extends the timbre of the conical piccolo conventionally used exclusively down to low c (c1), using simple and inexpensive means, and to design a conical piccolo of the above type extending to low c (c1) in such a way as to achieve correct tuning coupled with evenness of tone and an equal sound in all three registers (octaves), an easier and more reliable response, especially in the difficult third octave, and the timbre to which musicians are accustomed, as with the conventional conical piccolo extending to low d (d1).
In an embodiment, the present invention provides a piccolo including a cylindrical headjoint with an embouchure, a stopper including an adjustable seal disposed in a free end of the cylindrical headjoint, and a conical body having tone holes. The tone holes include a single tone hole corresponding to c2 and an end tone hole at a free end of the conical body. The end tone hole is lower than the note d1 and extends at least to the note c1.
Exemplary embodiments of the present invention are described in more detail below with reference to the drawing, in which:
Embodiments of the present invention address the above described aspects in that the body extending to low c (c1) has been completely redesigned, and features only one thumb hole and an associated newly designed hole-setting scheme. The invention replaces the tonally inadequate attempts hitherto to design a conical piccolo extending to low c (c1) and featuring two c2 thumb holes—designs rejected by musicians.
This design, featuring only one c2 thumb hole and extending to at least low c (c1), allows provision of a new combination of tone holes—a so-called hole-setting scheme—by means of which the above-described previous disadvantages have been eliminated. The instrument's entire range displays an even sound, purity and excellent response, offering optimum artistic possibilities and boasting a timbre, feel and playability identical to those of the conical piccolo extending to low d (d1).
One embodiment of the invention includes a hole-setting scheme with one c2 tone hole for the thumb, extending to low c (c1) and featuring the following dimensions for concert pitch a1=440 Hz and closed g-sharp construction.
A hole setting scheme for tue concert pitch a1=440 Hz with tue following distances between the mids of tue holes, measured from tue embouchure to the tone hole in question and stated in mm, is set forth in the following. The dimensions shown are representing the theoretical values of the length of the air column without consideration of a fine tuning (for example, due to changing temperatures or playing style):
d-sharp2 (e-flat) tr.—84.30
d2tr.−95.40
c-sharp2 (d-flat)—105.00
c2 (thumb hole)—116.00
b1—126.70
a-sharp1(b)—139.10
a1—151.50
g-sharp1 (a-flat) dpl.—160.50
g-sharp1 (a-flat)—162.00
g1—174.30
f-sharp1 (g-flat)—186.70
f1—199.20
e1—216.50
d-sharp1 (e-flat)—231.50
d1—250.50
c-sharp1—269.40
c1 (end tone hole)—292.00
and with a maximal permissible deviation of +/−0.5%.
Tone-hole diameters in mm:
embouchure 8.50 and 10.50 (oval)
d-sharp2 (e-flat) tr.—4.40
d2tr.—4.40
c-sharp2 (d-flat)—4.20
c2 (thumb hole)—5.90
b1—5.50
a-sharp1 (b)—5.80
a1—6.00
g-sharp1 (a-flat)dpl.—5.90
g-sharp1 (a-flat)—6.20
g1 6.40
f-sharp1 (g-flat)—6.80
f1—7.50
e1—7.80
d-sharp1 (e-flat)—7.70
d1 —7.90
c-sharp1—7.90
c1 (end hole)—8.80
And with a tolerance of +/−0.9 mm.
There are two basic piccolo designs: closed g-sharp key and open g-sharp key. With the open g-sharp design the same dimensions apply to the same concert pitch a1, with the difference that the duplicate g-sharp tone hole, g-sharp1 (a-flat) dpl., becomes superfluous and the g-sharp1 (a-flat) tone hole is placed in the tone-hole row. The hole-setting scheme in accordance with certain embodiments of the invention also extends to such a design.
The hole-setting scheme is based on concert pitch a1=440 Hz, though sounding an octave higher. As stated earlier, concert pitch is not the same everywhere, thus differing piccolos are built, deriving from a conventional hole-setting scheme. The lengths are inversely proportional to the number of vibrations.
The following already known conversion formula applies to frequencies other than concert pitch a1=440 Hz:
The conical piccolo depicted in the
The body (2) of a conical piccolo represented in the drawing is a closed g-sharp model, which has a second (duplicate) g-sharp hole: g-sharp dpl. It should be emphasised in this context that the new hole-setting scheme according to the invention for conical piccolos is equally advantageous whatever the material, be it wood, metal, plastic or a combination thereof. Designs are also possible that extend below c1, and the body can be either single- or double-jointed (as with the concert flute).
While the invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
---|---|---|---|
10 2010 027 462.3 | Jul 2010 | DE | national |
10 2011 010 124.1 | Jan 2011 | DE | national |