DE9209461U1 - Grand piano - Google Patents

Description

Frank Lenz, Herrenstrasse 7, D-7530 Pforzheim
Grand piano

The invention relates to a concert grand piano according to the preamble of claim 1.

A concert grand piano of this kind has been built in an unchanged form for around 140 years. A soundboard arranged in the grand piano, which has the typical grand piano shape, serves to transmit sound. Legs are arranged at three ends of the grand piano, which support the supporting structure made of pressed bentwood. A cast plate is arranged in the grand piano itself, which absorbs the forces resulting from the tension of the strings. In order not to take up too much space, the strings are arranged crosswise, so that two bridges are necessary to transfer the vibrations of the strings to the resonance surface. However, this leads to an undesirable stiffening of the resonance surface, which has a negative effect on the sound characteristics of the grand piano. The framing of the bentwood frame also creates a sound shading characteristic of the grand piano. The grand piano itself is closed by a lid, which is attached to one side of the grand piano and supported by a stand on one side. This stand can be inserted into two different openings, if required, to fully and half open the lid. The cast plate itself rests on the edge of the soundboard and thus dampens the vibration of the soundboard (Meyer, JüYgen; "Acoustics and musical performance practice", 2nd edition, page 77).

Furthermore, a piano by David Klavins is known in specialist circles. He attempted to create a new and enlarged string system with an enlarged soundboard surface. This is a piano with an upright acoustic system with a standing playing mechanism, with only one bridge when the strings are tensioned straight. In order to enable optimal sound transmission, however, the keyboard must be arranged in a higher position than on a normal piano and due to the straight arrangement of the strings, a construction height of 3.70 m is required. The enlarged soundboard surface leads to an un-"heard of" sound output, fullness of sound and carrying capacity of the tone.

Based on this state of the art, the invention is based on the object of developing a concert grand piano of the type mentioned at the beginning in such a way that acoustic optimization and sound transmission takes place in every respect.

This task is solved by the characterizing features of claim 1. In this design, a functional separation of the supporting elements and the sound elements takes place. The resonance surface is therefore no longer hindered in its vibrations by the rigid supporting structure. In addition, the supporting structure is designed in such a way that it supports sound transmission. The dissolution of the known shape of the grand piano also makes it possible to make the resonance surface larger and to achieve optimal sound transmission by arranging the bridge as centrally as possible on the resonance surface.

The result is an aesthetic overall picture that incorporates the individual elements into the visual appearance of the instrument. It becomes clear that the grand piano has a sound surface and not a sound body like a guitar. The elimination of the grand piano frame reduces the sound shading typical of the instrument, so that a more even diffusion of the direct sound can take place. The previously optically highly complex cast plate construction thus gives way to a clear appearance.

In a design according to claim 2, the resonance surface is designed with a reinforced edge, so that a flat vibration behavior of a plate-shaped object is formed. The curvature according to claim 3 enables the aesthetic emphasis of the surface character of the resonance surface. In addition, the stiffeners can be designed in several parts, so that the structural design is also significantly simplified compared to conventional grand pianos. In a design according to claim 4, the supporting structure is located below the resonance surface, and the viewer is presented with the image of a freely floating surface that is actually held to the legs of the grand piano. A frame is still present, but it now consists of a stiffener that is arranged on the edge of the sound surface and gives it the shape of a tensioned membrane.

The optimization from an acoustic point of view is supported in the design according to claims 5 and 6 by the fact that the supporting structure, whether completely formed as a cast plate or composed of several parts, does not prevent the sound from spreading. In fact, the supporting elements can even be used to direct sound in the form of sound reflection.

In a design according to claim 7, the already proven experience of Klavins can also be used for a grand piano. The structural design makes it possible to provide a grand piano with a straight string, since this type of string requires extremely long strings. This type of string can only be realized through the loose construction of the concert grand piano, since otherwise the volume of the instrument would give an impression of being too huge. In this respect, the aesthetic design of the instrument contributes to improving the sound in the first place.

With a design according to claim 8, the possibility is created to also carry out a bridge pressure adjustment on a grand piano. This is necessary, for example, in order to readjust the vibration behavior of the grand piano's sound strings.

In a design according to claims 9 and 10, the clear concept of acoustic optimization is continued by the previously known cover being designed as a reflector that is optimized according to acoustic aspects. As if that were not enough, in a design according to claims 11-14, an adjustment mechanism is also provided that can additionally adjust the reflection surface designed according to acoustic guidelines to any conceivable room acoustic situation. This results in a more even diffusion and reflection of the direct sound via the reflector into the concert hall, whereby the reflector has an acoustically optimized reflection surface design with balanced reflection behavior.

Finally, the acoustics can be further optimized by choosing the material for the reflector according to a design according to claim 15. Glass is chosen as the material, which has a low absorption level. For this purpose, the adjustment mechanism for the reflector must be constructed in such a way that stresses acting on the reflector are permanently avoided, but this is consciously accepted in view of the material-specific positive properties of glass.

Further advantages emerge from the subclaims. The invention is explained in more detail below using an exemplary embodiment. They show:

Fig. 1 a concert grand piano without reflector, Fig. 2 the concert grand piano of Fig. 1 with attached

Reflector with adjustment mechanism,

Fig. 3 a top view of the grand piano with the lid removed and

Fig. 4 a section through part of the supporting structure.

As is common practice, a concert grand piano has three legs 10 on which a supporting structure 11 is supported, which carries both the resonance surface 12 and the keyboard 14. The supporting structure

Several sound strings 13 are attached to the structure, which are

Keyboard is usually operated by a mechanism and

The vibrations generated thereby are transmitted via a bridge to the resonance surface 12.

As can be seen from Fig. 1, the resonance surface 12 is spatially separated from the supporting structure 11. This spatial separation allows the resonance surface to be designed in such a way that it can vibrate like a freely supported plate. In order to achieve a clear vibration behavior, the resonance surface 12 is reinforced along its edge by stiffeners 12a, which correspond to the previously known frames, but nevertheless underpin the resolution into the functional elements of supporting structure and resonance surface, in particular through their inward-facing bevels. The stiffeners also support the reflection surface 12 and are supported on the legs 10.

The resonance surface is mounted on the legs 10 and is penetrated by the legs themselves. However, this penetration takes place in the edge area so that the sound characteristics are not affected. The resonance surface 12 is located below the supporting structure 11 so that the vibrations of the strings can be transferred downwards via the bridge to the resonance surface in the known manner.

The concert grand piano is constructed in such a way that the viewer can already see the separation into functional elements from the outside. This separation is also necessary because the grand piano is longer than a normal concert grand piano and the sound strings 13 are straight-stringed. This makes it possible to provide only a single bridge 16 on the resonance surface, which transfers the vibration of the strings to the resonance surface 12. The supporting structure 11 has sound passage openings 11b, whereby the supporting structure itself has reflection surfaces lic shaped according to acoustic aspects, so that a sound channel into the audience area can be realized.

The support structure 11 with the cast plate 11a is height-adjustable in the area of the legs 10 using an adjustment device 17. This makes it possible to adjust the distance between the sound strings 13 and the bridge 16. This bridge pressure adjustment can, however, improve the sound characteristics of the entire instrument. In terms of construction, the adjustment mechanism can be a conventional mechanical adjustment or an automated adjustment using known adjustment mechanisms such as tension screws, hydraulic motors, ball screws or similar.

The concert grand piano has a reflector 18 that also functions as a cover. From an acoustic point of view, this reflector 18 is designed as a double-curved surface and is supported at at least three points, preferably in the area of the legs 10. The distance between the reflector 18 and the resonance surface 12 is less than half the radius of curvature of the reflector curvature. As a result, the reflected sound rays diverge as if they were coming from a focal point behind the reflector. This enables a more even diffusion of the direct sound via the reflector into the concert hall through an acoustically optimized reflection surface design with balanced reflection behavior.

As can be seen in particular from Fig. 2, an adjustment mechanism 19 is provided for the reflector, which engages at its three support points and is preferably supported on the legs 10. The engagement can take place on the stand 23, but is also possible on the two other support points. The aim is for the reflector to lie approximately in the middle of the resonance surface. This can be done both by mechanical adjustment and by hydraulic actuation. Of course, other drive mechanisms and adjustment mechanisms familiar to the expert are also possible. In the specific embodiment in Fig. 2, the reflector is connected to elements that converge approximately at the center of gravity of the reflector 18 and are connected to the adjustment mechanism 19. At the upper end of the stand there is

a joint that merges into an inner tube 21. Each element, all of which lie approximately in the plane of the reflector surface and form an articulated train that supports the reflector, consists of an outer tube 20 and an inner tube 21 that extends into this outer tube. Both tubes are mounted so that they can move relative to one another, so that no tension can arise when the adjustment mechanism is operated. The outer tube 20 has disks 22 at its end that are mounted so that they can rotate concentrically. When the adjustment mechanism is moved, tensions are thus permanently avoided that could otherwise place undue strain on the cover and thus lead to a distortion of the sound image. Finally, the reflector 18 is made of clear or opaque glass, which has optimal properties for sound reflection due to its low absorption coefficient. If the glass is chosen to be opaque, the overall emphasis of the instrument is further improved from a design perspective, as another element that is essential for sound transmission catches the viewer's eye. The sound element becomes an experience of the acoustic and static elements. The overall appearance of the instrument radiates elegance and high quality, and it is clear that the instrument has been designed according to the latest acoustic findings. For this purpose, the acoustic system is also brought into the light of day and no longer hidden behind the sides as before. This results in a clearly structured appearance that corresponds to the functionality of the instrument.

Claims (14)

Protection claims 1. Concert grand piano with a supporting structure (11) supported on legs (10), a resonance surface (12) and several sound sides (13) which are operated via a keyboard (14) and transmit the vibrations generated thereby to the resonance surface (12) via a bridge (16), characterized in that the resonance surface (12) is arranged spatially separated from the supporting structure (11) and is supported as a plate accessible to free vibration. 2. Concert grand piano according to claim 1, characterized in that the approximately horizontal resonance surface (12) is stiffened along its edge by stiffening (12a) and projects beyond the supporting structure (11) provided with a cast plate (Ha). 3. Concert grand piano according to claim 2, characterized in that the stiffeners (12a) are bevelled inwards and support the resonance surface (12). 4. Concert grand piano according to one of the preceding claims, characterized in that the resonance surface (12) mounted on the legs (10) and penetrated by the legs is arranged below the supporting structure (11). 5. Concert grand piano according to one of the preceding claims, characterized in that the supporting structure (11) which is visible from the outside and loosened by openings (lib) in the shell absorbs the tension forces of the sound strings (13). 6. Concert grand piano according to one of the preceding claims, characterized in that the sound passage openings (lib) are partially covered by curved reflection surfaces (lic) of the supporting structure (11). 7. Concert grand piano according to one of the preceding claims, characterized in that the straight-strung sound strings (13) transfer their vibrations to a single bridge (16) arranged on the resonance surface (12). . Concert grand piano according to one of the preceding claims, characterized in that the supporting structure (11) with the cast plate (Ha) in the region of the legs (10) is designed to be height-adjustable via an adjusting device (17). . Concert grand piano according to one of the preceding claims, characterized in that it has a cover designed as a reflector (18) which is designed as a double-curved surface and is supported at at least three points in the region of the legs (10). 10 ¹ ,. Concert grand piano according to one of the preceding claims, characterized in that the distance of the reflector (18) to the resonance surface (12) is smaller than half the radius of curvature of the reflector curvature. . Concert grand piano according to one of the preceding claims, characterized in that the plane in which the reflector (18) is located can be changed in its position at its three support points via an adjustment mechanism (19). 12. Concert grand piano according to claim 11, characterized in that the reflector (18) is connected to elements which converge approximately at the center of gravity of the reflector and are connected to the adjustment mechanism (19). 13. Concert grand piano according to claim 12, characterized in that the element of the articulated cable carrying the reflector (18) is constructed from an outer tube (20) and an inner tube (21) immersed in the latter, which move relative to one another when the adjustment mechanism (19) is preferably actuated hydraulically. 14. Concert grand piano according to one of claims 11-13, characterized in that each of the tubes (20; 21) is provided with a disk (22) at its end and that the disks of all the tubes are concentrically mounted to rotate relative to one another at the center of gravity - 3 of the reflector surface. 15·. Concert grand piano according to one of the preceding claims, characterized in that the reflector (18) consists of clear or opaque glass.