EP2509067A1 - Membranophone musical instrument - Google Patents

Abstract

The instrument has a membrane (1) e.g. plastic film, stimulated for vibration for producing sound. The membrane includes an annular region (5) and a circular ring segment-like region (6) with continuous openings (3, 4) that run transverse to a surface of the membrane, where air flows through the openings. The openings are provided in a regular pattern, and have different arrangement densities and/or sizes. The membrane includes a central region (7) without openings, where the surface is closed in the central region. The membrane is made of a biaxial oriented polyethylene terephthalate. An independent claim is also included for a method for reducing a sound intensity of a membranophone musical instrument.

Description

The invention relates to a membranophones musical instrument with at least one to be stimulated to vibrate the sound production membrane.

Membranophone musical instruments, also referred to as membrane phones, are those which have a membrane for producing sound. This membrane may be a strained animal skin or such an animal skin, but also a plastic film, a paper or the like.

In the group of membraneophones, a differentiation is now made according to the type of excitation of the membrane between those which are struck, that is, percussion instruments, and those in which the membrane is caused to oscillate by blowing. The former group includes e.g. Drums, timpani, djembes and bongos. To the second mentioned group belongs e.g. the kazoo.

Membranophone percussion instruments often constitute essential components of percussion instruments, which are a collection of percussion instruments, typically drums and cymbals.

Membranophones, such as drums, bongos and timpani, often have one, usually one-sided opened, in any case, on the other side covered with the membrane resonating body in which an air column through the oscillating Membrane is excited to corresponding oscillatory movements, whereby the sound is generated and amplified accordingly acoustically. Since these resonance bodies are often very voluminous, the sound produced by the membraneophone by striking or otherwise exciting the membrane is often very loud. This can lead to problems, even if a loud sound is desired in different situations. For example, if the membranophone musical instrument is played in a comparatively small space, or together with other musical instruments that inherently have a low sound volume, it may happen that the overall membrane sound is too loud and appropriate action must be taken. In conjunction with other instruments, it is then often necessary to adjust their sound volume by electrical amplification (converting the acoustic signal into electrical signals by means of a microphone, amplifying the electrical signal and outputting the amplified signal via loudspeakers by reconversion from electrical to acoustic).

Even in practice situations in which the musician rehearses pieces of music with his membrane microphone alone, a lower sound volume of this musical instrument is often desired.

There are approaches with which a reduction of the sound volume can be achieved, which, however, each have disadvantages. Thus, it is known, for example, to apply additional damping foils or mats to the membrane in the case of the membraneophonic percussion instruments in order to reduce the intensity of impact with which the instrument is excited and, on the other hand, to dampen the vibration amplitudes of the oscillating membrane. Thus, although a reduction of the sound volume can be achieved, but this is also at the expense of the sound characteristics of this instrument, which is changed by this measure. Also, it is a known measure, to reduce the sound volume of a Membranophons sound-absorbing material, such as ceilings, foam body or the like. Introduce into the resonator of the instrument to thereby achieve a damping of the oscillating air column and thus a reduction of the sound volume. However, these measures also have a direct influence on the sound characteristic of the instrument, since usually the fundamental and different overtones are attenuated in different weight and strength, so in total there is a changed with respect to this tonal composition sound.

Here is to be remedied with the invention and given a membranophones musical instrument, which allows without or largely without changing the sound characteristics, a reduction in sound volumes over a comparable, conventional membranophone musical instrument. In a further aspect of the invention, a novel membrane for a membranophones musical instrument is to be named. Finally, a method is sought with which the sound volume of a membranophone musical instrument can be reduced.

The solution of this problem with respect to a corresponding properties having membranophone musical instrument is characterized by a membranophones musical instrument having the features of claim 1. A problem-solving membrane is designated in claim 9. The desired method can be inventively designed as specified in claim 10. In the dependent claims 2 to 8 advantageous developments of a membranophone musical instrument according to the invention are given.

The basic idea of the invention is that the sound volume of a membranophone musical instrument depends, among other factors, such as the amplitude of vibration of the excited membrane, in particular, on the volume of the air column excited to oscillate with the membrane, and thus on the area of the membrane. The larger this volume is, the more vibrational energy is transferred from the membrane to the air column and the louder the instrument sounds. Here, with the invention, a way was found over which without any other change of the membranophone musical instrument (change of the resonating body, the material or the like.) A reduction in the energy transfer of the oscillating diaphragm with a predetermined amplitude with respect to the same amplitude oscillating membrane of an otherwise identical conventional membranophone musical instrument can be achieved. This is inventively achieved in that the membrane has transversely extending to its surface, through openings through which air can flow. These openings cause that with oscillating membrane is no longer completely entrained in this adjacent air and excited to vibrate, but that at least parts of the surrounding air flow through the membrane and so far delivered to these parts of the air from the vibrating membrane no energy or can be transferred to this. But this inevitably reduces the sound volume of such a membrane-perforated membranophone musical instrument. The openings can be introduced in various ways in the membrane. Thus, it is possible to subsequently provide a membrane with openings, in particular to perforate. Equally, it is also possible to produce the membrane, especially if it is made of plastic, already provided with openings. Here, for example, a production variant can be selected in which a plastic membrane is not drawn as a film, but is formed from threads by weaving or knitting, leave at locations where openings are provided, corresponding openings and secured or secured by knotting or the like ,

The arrangement of the openings above the membrane can in principle be designed as desired. Thus, it is conceivable that openings are provided distributed over the entire membrane in a uniform distribution pattern. Also, the openings may be arranged distributed arbitrarily. However, not least for maintaining the stability of the membrane, it is preferred if the membrane has at least one region with openings arranged therein and at least one region with openings arranged therein and at least one region without openings in which the surface is closed. Of course, such a regional division can also be designed with several areas with openings and / or several areas with closed membrane surface. Particularly efficient and with comparatively few openings, ie a membrane that is not excessively weakened in terms of stability, a reduction in the sound volume of a membranophone musical instrument can be achieved if the openings are arranged in at least one region of the membrane, which oscillates averaged over at most the first five, in particular the first three, vibration modes of the membrane after the start of the excitation with high, preferably the highest amplitude. The diaphragm attached to the edge of a membranophonic musical instrument vibrates after excitation, depending on its geometry and stress, in a defined vibrational mode pattern. In the individual oscillation modes, regions with maximum deflection and other regions in which the nodes of the standing waves lie as lines or surfaces in which the deflection is close to zero or significantly lower than in the regions of maximum amplitude result. It will be appreciated that energy transfer to the surrounding air is primarily through the areas where the diaphragm is vibrating at a high amplitude, so introducing apertures in these areas provides a much more noticeable and significant effect for reducing the sound volume.

The openings may in particular be arranged at least in one area in a regular pattern. This is easier to manufacture and allows reproducible production. In addition, the openings can be packed comparatively close, e.g. in such areas with high vibration amplitudes.

Another design option, with which the degree of reduction of the sound volume can be influenced or set up, is that different areas with openings in different arrangement density can be provided.

Although basically all membranophone musical instruments according to the invention can be formed, it is of particular importance in particular in the case of membraneophonic percussion instruments. These usually sound much louder than eg blown membrane phones, so that there a reduction in the sound volume has a greater practical significance. In addition, ensembles are much more likely to use membranophone percussion instruments with other instruments (eg timpani in classical orchestras) and drums in groups of modern popular music) as such membrane-blown membrane-stimulated membrane.

Since, as already apparent from the above explanations, the degree of reduction of the sound volume of a given membranophone musical instrument is clearly dependent on the number of openings, the arrangement of the same and their size, the sound volume can by selecting a membrane with appropriately defined, above Parameters are influenced or adjusted. Thus, in order to be able to variably adjust the sound volume in a membranophone musical instrument, according to the invention such a membranophone musical instrument can have a set of at least two membranes, with openings introduced therein in different numbers, sizes and / or distribution. By replacing the respective membrane, the membranophone percussion instrument can be adjusted in terms of its sound volume and adapted to the respective needs. Since replacement of a membrane can be done relatively easily and quickly in many modern membranophone musical instruments, even a change in the course of a performance of a musician, e.g. in the context of a break between two pieces of music, possible.

Basically comes, as already stated, for a membranophones musical instrument almost any material for the membrane in question, from which a membrane can be produced at all. In addition to animal hides and skins, these are e.g. Paper and plastic. For a membranophone musical instrument according to the invention, however, a plastic, in particular a biaxially oriented polyethylene terephthalate (boPE), is preferred as the material for the membrane. This material is used today, e.g. regularly used for the production of membranes of membranophonic percussion drums.

Another aspect of the invention is, as already stated, in a membrane which has transversely extending to its surface, through openings through which air can flow. Such a membrane is suitable, as can be seen from the above representation, for use in membranophone musical instruments to reduce their sound volume.

Finally, one aspect of the invention is a method for reducing the sound volume of a membranophone musical instrument having a diaphragm to be vibrated for sound generation, in which air is allowed to flow through the membrane extending transversely to its surface and fully penetrating the membrane ,

Fig. 1

eine schematische Aufsicht auf die Membran eines membranophonen Musikinstrumentes mit darin in erfindungsgemäßer Weise angeordneten Öffnungen.

Further advantages and features of the invention will become apparent from the following description of an embodiment with reference to the accompanying figure. It shows:

Fig. 1

a schematic plan view of the membrane of a membranophone musical instrument with therein in accordance with the invention arranged openings.

In Fig. 1 is a highly schematic schematic representation of a membrane of a membranophone musical instrument according to the invention and generally designated by the reference numeral 1. This membrane 1 is stretched in a concrete structure of the membranophone musical instrument via a holding frame, which holding frame, for example, a circumferential edge of a resonator can a, and is held by means along their circular shaped circumference distributed clamping devices 2 in taut strained position. The membrane 1 according to the invention is preferably made of a plastic material, in particular of a biaxially oriented polyethylene terephthalate (boPE). It differs so far and in the features described above in nothing of a conventional membrane of the same material of a membranophone musical instrument of the same design. Incidentally, it can be clamped and used on an identically constructed frame or sound box as contained in a conventional musical instrument of this type. The special feature of the membrane 1 are the openings 3, 4, which are transverse to the surface of the membrane 1, the membrane 1 penetratingly guided therethrough and are formed so that air can flow through them. These openings 3, 4 are in different, here schematically indicated areas, an annular, on the membrane 1 outside area 5 and an adjacent to the area 5 adjacent, closer to the center of the membrane 1 located, annular segment-shaped region 6, each arranged in different density. While the regularly arranged openings 4 in the region 5 have a comparatively high surface density, the surface density of the openings 3 in the region 6 is markedly lower, whereby the openings 6 are arranged in a regular pattern there as well. In the central region 7, the membrane 1 has no openings, so here has a closed surface.

If this membrane is e.g. stimulated to vibrate by hitting the areas 5 and 6 of the membrane 1, in which openings 3 and 4 are arranged, transmit significantly less energy to the surrounding air than in the case of a comparable membrane (of the same material and dimensions) would, which has no openings 3, 4. This lower energy transfer ultimately results in a reduced sound volume of the musical instrument equipped with this membrane 1.

The arrangement of the openings 3, 4 or provided with these openings 3, 4 areas 5, 6 is shown purely schematically in the figure. The regions 5, 6 can also be arranged and dimensioned in a completely different manner, wherein it is preferred to provide openings where the membrane 1 oscillates in the maximum five, in particular a maximum of three vibrational modes first resonating after excitation of the membrane, if these modes are considered averaged. Of course, it is also possible to provide on the membrane 1 instead of two different areas 5, 6 with openings 3, 4 in different surface density only one area with openings or multiple areas with openings in which the openings are arranged in the same area density.

The invention has shown that the openings in the membrane otherwise do not change the sound characteristic of a musical instrument equipped with such a membrane, that this sounds in particular with the same overtone pattern. Only a reduction of the sound volume is achieved, whereby the degree of this reduction can be changed and adjusted by selecting the number, the distribution and / or the size of the openings.

It will be appreciated that this invention provides a great deal of opportunity for the use of corresponding instruments in new orchestration, solving existing problems in the art.

Finally, it should be pointed out here that an as in Fig. 1 It can also be used in connection with novel instrument types of membranophone musical instruments, in which the sound volume of the to reduce excited membrane.

LIST OF REFERENCE NUMBERS

1

membrane

2

tensioning device

3

opening

4

opening

5

Area

6

Area

7

Area

Claims (10)

Membranophone musical instrument with at least one diaphragm to be stimulated to produce sound (1), characterized in that the membrane (1) has transversely to its surface extending through openings (3, 4) through which air can flow. Membranophone musical instrument according to claim 1, characterized in that the membrane (1) has at least one region (5, 6) with openings (3, 4) arranged therein and at least one region (7) without openings in which the surface is closed , Membranophone musical instrument according to claim 2, characterized in that the at least one region (5, 6) of the membrane (1) with openings (3, 4) arranged therein is one which averaged over at most the first five, in particular the first three, Vibration modes of the membrane (1) after the start of the excitation with high, preferably the highest amplitude oscillates. Membranophone musical instrument according to one of the preceding claims, characterized in that the openings (3, 4) are arranged at least in a region (5, 6) in a regular pattern. Membranophone musical instrument according to one of the preceding claims, characterized in that the membrane (1) at least two regions (5, 6) arranged therein with openings (3, 4) with different arrangement density and / or size of the openings (3, 4). Membranophones musical instrument according to one of the preceding claims, characterized in that it is a percussion instrument. Membranophone musical instrument according to one of the preceding claims, characterized in that it comprises a set of at least two membranes (1) to be fixed alternatively on the musical instrument with openings (3, 4) in different numbers, sizes and / or distribution. Membranophone musical instrument according to one of the preceding claims, characterized by a membrane (1) made of plastic, in particular biaxially oriented polyethylene terephthalate (boPE). Membrane for a membranophone musical instrument, characterized in that it has transverse to its surface extending through openings (3, 4) through which air can flow. Method for reducing the sound volume of a diaphragmophone musical instrument which has a membrane to be vibrated for generating a sound, characterized in that openings which extend transversely to the surface and penetrate the membrane completely are introduced, through which air can flow.

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