DE1225033B - Slide trombone - Google Patents

Description

Slide trombone The invention relates to improving the playing technique the slide trombones, especially the deep slide trombones with additional valves.

The pipe of a musical instrument that is of a certain length produces only a single tone. If the lip tension and the breath pressure are tightened (so-called overblown) it can be achieved that the column of air in the tube of the instrument oscillates in the multiple frequencies corresponding to the overtone series and thus the tones of the overtone series can be produced individually as independent tones. These notes, including the root note, represent the basic scale of the instrument. The slide trombone has a range of around three and a half octaves. So there is z. B. the basic scale of an F bass trombone from the notes Fl, F, c, f, a, cl, es', fl, gl, al, bl, c22. In the slide trombone, the slide mechanism is used to fill in the pitch gaps in this scale instead of the valve mechanism otherwise provided for this purpose in brass instruments. By pulling out the slide, the tones of the basic scale of the slide trombone can be lowered by a certain number of semitone steps, each of which is determined by the distance by which the slide is pulled out. There are seven specific positions (positions) of the train, namely the original position when the train is drawn in and six positions reached by pulling out the train. The bass trombone, if it is provided with one or more additional valves, has a shortened slide that has only six positions.

Since the indentation of six semitones is not enough to fill the gap of twelve semitones between the natural tone No. 2 and the natural tone No. 1 , the slide trombone was provided with an additional valve attached to the bell part as early as 1839, through which the required pipe extension can be achieved. This additional valve was first attached to the tenor trombone, and in 1921 also to the bass trombone.

If slide trombones were equipped with additional valves in the previous way, this was done exclusively for the purpose of transforming the trombone into a lower type of trombone by means of the valve or two additional valves, e.g. B. a tenor trombone in a bass trombone or an F-bass trombone in an E-flat bass trombone or a B-double bass trombone, and thus by superimposing the sound scales of the individual types of instruments to achieve a closure of the tone gap between the natural tones No. 2 and 1 . All known slide trombones, including those provided with additional valves, have several critical sections in their middle and low scale, in which certain tones can only be performed when the slide is very far or completely withdrawn, while others can only be performed when the slide is almost or completely retracted. These are mainly the notes in the middle of the major octave and in the transition area from the major octave to the contra octave. As a result, rapid tone sequences, such as passages, complicated tone figures, etc., in which such tones occur or follow one another, cannot be carried out with the known slide trombones. The reason for this is that the physical moment of inertia does not allow the relatively heavy and long metal tube of the train to be pulled back and forth over long distances in a fraction of a second, as is required in fast Tonfolaen. Every quick and far back and forth pulling of the pull also jolts the instrument and thereby endangers the safety of the sound approach. At the same time, it causes considerable physical strain on the player, especially when it comes to the lower types of trumpets. The total distance over which z. B. in the F-bass trombone the train must be pulled out from the first to the sixth position on the so-called lead screws, is about 650 mm. As a result of these train-technical limitations of the known train trombones, it was not possible to use fast passages and other tone sequences, as they are e.g. B. in the bass trombone parts written for the valve bass trombone of the works of Giuseppe Verdi are to be performed with a slide trombone.

The mechanism of the auxiliary valve on the slide trombone must be judged according to completely different structural principles than the valve mechanism on the actual valve brass instruments (e.g. horn and trumpet) or the mechanism of the keyed instruments (e.g. saxophone). Correspondingly, the mechanical principles of changing the length of the tube, including the resulting ÖT! Ffiechnii, which are valid for these instruments, can by no means be applied to the slide trombone. Pure valve or keyed instruments can be played without any technical. ' Difficulty. held with both hands and the valve or flap mechanism , if necessary, can also be operated with both hands. The bass tuba and saxophone even have a strap to hold the instrument.

In contrast to this, the unwieldy, elongated slide trombone, the balance of which changes with every pulling movement, is held with the left hand alone. In principle, all fingers of the left hand are required to hold the instrument, while the right hand can only operate the train. Therefore, only the left hand of the trombonist is available to operate one or more auxiliary valves while playing. When an additional valve was attached to the slide trombone for the first time in 1839 , the structural principles of attaching and operating valves that apply to pure valve instruments could not be applied here. As a result, the additional valve was initially designed as a control valve that was operated with the right hand, which in each case made it necessary to interrupt the game. At that time, spring pressure valves for wind instruments were already well known. If the technical conditions of the slide trombone were the same as those of the pure valve instruments or the keyed instruments, the additional valve would undoubtedly have been attached from the beginning in the form of a spring pressure valve. Only later was it designed to be such and its operation was assigned to the thumb of the left hand holding the instrument by means of a leather loop leading to the valve lever. There was no possibility of assigning the operation of the additional valve on the slide trombone to a finger other than the thumb of the left hand, although valve operation with fingers other than the thumb and even with different fingers of both hands had long since been common with pure valve instruments and accordingly, the valve operation was common with the valve instruments (e.g. the Ophikleide). This possibility is also up to the present, i. H. has not been recognized in the course of about 130 years, even in the case of the installation of two additional valves. The additional valve on the slide trombone has therefore only been built in the whole world so that it is operated by the thumb. This is the reason why it is called "thumb valve" in the technical language of all countries (cf. Cecil Forsyth, Orchestration, London 1914/48: "The German tenor bass trombone with the thumb valve").

Sometimes a pull rod or a pressure lever for the thumb is provided instead of the leather pulling loop. When pulling trombones, which are provided with two additional valves, z. B. on the F-slide trombone designed by D ehme 1 in 1921 with additional valves for Eb and low B, the pressure plates of the two valve levers are designed to lie close to one another. Are the awkwardness of winding-changing of the thumb of the pressure plate to the other to, the verminderny, a 'n, a Mander 1 ying: edges of the beiden'Druckplatten. m . t provided small rollers over which the thumb slides. Since it naturally takes a certain amount of time to return the thumb after a valve lever has been depressed, to bring it back to the adjacent pressure plate and then to depress it, alternating operation of the two valve levers with the speed required to execute quick passages, etc. is required, impossible. For the same reason, alternating operation of the two additional valves with the effect of a legato is impossible.

Originally it was when two additional valves were attached to the slide trombone one valve designed as a thumb valve and the other as a control valve.

It is the object of the invention to eliminate the drawbacks of the previously known draw trombones. Notwithstanding the above, previously known design principles, it is achieved by the subject matter of the invention is that the wide train movement in the field of natural tones no. 1 to 3 can be avoided by means of additional valves, and that particularly in the bass respectively. the double bass trombone, where the need for further pulling movements limits the usability of the instrument to a large extent.

Due to the length ratios of the valve tubes and the main tube of the slide trombone calculated according to the invention, it has been made possible that the slide of the trombone, instead of being pulled out in the lower positions , can predominantly remain in the basic position 1 or otherwise only be pulled out very briefly needs when fast tone sequences require it. As a result, the draw-related disadvantages of the known slide trombones have been eliminated.

It was therefore necessary to determine the length ratios of the two valve tubes to each other as well as each individual valve tube or both valve tubes together to Main pipe to be determined so that each by substantial or complete pulling out of the train to be effected extension of the main pipe instead of operating the train with Can be effected using one or both additional valves.

According to the invention, this is achieved in that a slide trombone is provided with two additional valves, namely a one-and-a-half- tone valve and a two-and-a-half-tone valve, so that the basic tuning of the instrument when the one-and-a-half-tone valve is opened (Fig. 1 and 2, No. 2) by three semitones and when opening the two and a half tone valve (Fig. 1 and 2, No. 1) is lowered by five semitones. The two valves can be connected to the main pipe either individually or together. When both valves are open, the basic pitch is lowered by three and a half tones. It should be noted here that there is only a deepening of three and a half tones and not about four tones, because the pipe lengths of the two valves are each dimensioned for a deepening of the basic mood by one and a half or two and a half tones. The addition of these two tube lengths therefore does not result in the tube length required to deepen the basic tuning by four tones, since the tube lengths required for each semitone step increase with the depth. The one-and-half tone valve, which lowers the basic tuning by three semitones, requires a pipe length of about 1 / 5.7 to 115 the length of the main pipe. The two-and-a-half tone valve, which deepens the basic tuning by five semitones, requires a pipe length of about 1 / 3.2 to 1 / 2.8 the pipe length of the main pipe. The length differences taken into account here (e.g. 1 / 5.7 to 115), which must be given to tune the instrument, are achieved by tuning slides on the valve tubes. In an F-bass slide trombone designed according to the invention with a main tube length of about 3680 mm, the one-and-a-half -tone valve has a tube length of about 650 mm and the two-and-a -half tone valve has a tube length of about 1250 mm.

It was also necessary in an expedient embodiment, the operation assign the two additional valves to two different fingers for a quick To enable valve operation similar to that of the pure valve instruments (e.g. horn, Valve trombone) is comparable.

This is achieved in 'that the Zweieinhalbtonventil (F i g. 1 and 2, no. 1) is provided with a tie-rod (F i g. 1 and 2, no. 3) with the thumb of the instrument holding left hand is operated, while for the half- tone valve (F i g. 1 and 2, no. 2) a pressure lever is attached (F i g. 1 and 2, no. 4), which with the third or fourth finger of the left hand or is operated with both fingers together. If the instrument is held in the usual way with the left hand, the first and the second link of these fingers have sufficient freedom of movement to operate this pressure lever. The pressure lever must be attached and designed perpendicular to the plane of the bell part with appropriate attachment of the valve so that its direction of movement when depressed coincides with the direction of movement of the first two members of the third or fourth finger. This direction is determined by the position of the left hand on the instrument.

By distributing the valve operation to two according to the invention different fingers will not only have the same common valve technology as with the pure valve instruments are possible, but also pure valve legato like with these.

The train trombone designed according to the invention has in its entirety Sound scale a playing technique fluency similar to that of pure valve instruments, especially the valve trombone. In particular, one according to the invention has trained F-bass slide trombone this technical fluency in the range of the big ones Octave and the transition from the major octave to the contra-octave, in which everyone is known Slide trombones can only be used to a very limited extent, for fast passages however, are completely unsuitable.

So much for a slide trombone designed according to the invention when used the additional valve is used like a valve trombone, it has this opposite the advantage of the possibility of an intonation correction, which is particularly important in the lower registers with the help of the train.

Claims (2)

Claims: 1. Slide trombone, characterized in that the two additional valves are designed as a one and a half tone valve and as a two and a half tone valve and can be connected to the main pipe independently or together. 2, slide trombone according to claim 1, characterized in that the additional valves are arranged so that they can be operated with different fingers. Considered publications: German Patent Specifications No. 528 853, 747 090.