EP0102379A1

EP0102379A1 - Improvements in pianos.

Info

Publication number: EP0102379A1
Application number: EP19830900939
Authority: EP
Inventors: Colin Howard Stanwell-Smith
Original assignee: Prutec Ltd
Current assignee: Prutec Ltd
Priority date: 1982-02-26
Filing date: 1983-02-28
Publication date: 1984-03-14
Also published as: EP0102379B1; JPS59500531A; DE3369217D1; WO1983003022A1

Abstract

Pianos dans lesquels une table d'harmonie (30) reliée aux cordes (12) par un pont (20) est construite de manière analogue aux organes vibrants d'un haut-parleur. Le piano peut avoir des tables d'harmonie séparées pour des gammes de fréquence différentes. La table d'harmonie peut être reliée aux bobines (70, 72) pour fonctionner soit comme dispositif d'entraînement, soit comme phonocapteur. On peut ainsi reproduire de la musique de fond par l'intermédiaire du piano ou ajouter des harmoniques au moyen d'un circuit de traitement pour modifier la tonalité du piano ou obtenir des effets spéciaux.Pianos in which a soundboard (30) connected to the strings (12) by a bridge (20) is constructed analogously to the vibrating organs of a loudspeaker. The piano may have separate soundboards for different frequency ranges. The soundboard can be connected to the coils (70, 72) to function either as a training device or as a sound sensor. It is thus possible to reproduce background music via the piano or to add harmonics by means of a processing circuit to modify the tone of the piano or obtain special effects.

Description

IMPROVEffENTS IN PIANOS

The present invention relates to upright pianos and the like stringed keyboard instruments.

In a conventional upright piano, the strings are mounted on a massive rigid frame and near their lower ends they extend over bridges which are attached to a soundboard rigidly secured to the piano casing and usually constituted by the back of the piano.

Traditional soundboards are made of planks about 10mum thick laid edge to edge and braced at right angles by bars which run under the bridges. Great care is taken to select wood with high sound propagation rates and low internal damping. Overstringing is common because it allows a better bridge position on the sound board.

However, problems arise because the base notes tend to be too near the edge of the soundboard and the treble notes lose volume because of the weight of the soundboard.

The present invention seeks to mitigate at least some of the foregoing disadvantages.

According to the present invention, there is provided a piano comprising a.frame, a plurality of taut strings supported on the frame and extending over a bridge and a soundboard coupled to the bridge, wherein the soundboard comprises a rigid member freely suspended relative to the frame by mounting means which enable the rigid member to move towards and away from the frame at least in the region of the bridge.

Thus the invention proposes the use, as the soundboard of a piano, of a member analogous to the vibratable membrane of a loudspeaker.

In the case of a relatively small soundboard, the rigid may be flexibly mounted about its entire periphery in the same manner as a loudspeaker cone but for larger soundboards the rigid member is preferably pivotable about an edge remote from the attachment to the bridge.

In the preferred embodiment of the invention, a piano comprises three bridges each connected to a respective soundboard. The soundboard for the base notes is pivotably mounted along a line remote from the bridge whereas the remaining two soundboards are flexibly supported in a rigid box by compliant mounting means extending about their peripheries.

In substituting the flexibly mounted vibratable member for the traditional soundboard, it is possible to draw on the experience in loudspeaker desig.n not available to early piano designers.

The rigid box may be in the form of a closed box so as to use- infinite baffle techniques and the box may be constituted by the casing of the instrument.

Alternatively, the box may have a front opening and a base baffle in the manner used in some conventional loudspeakers.

It is well known that many loudpeakers separate low, medium and high frequencies in order to optimise the design. The same technique is used in the preferred embodiment of the invention by arranging a plurality of vibratable members each covering a different range of frequencies.

Since the vibratable members are similar to loudspeaker discs or cones, it is possible for each member to cooperate with an electrical coil which may act as a drive, a pick-up or both.

The coil when used as a pick-up can enables sound recordings to be made directly from the soundboard of the piano. When used as a drive, it can, for example, enable a recorded piece of music to be reproduced while superimposing on the sound played back the notes manually played on the instrument. A still further possibility is that the sound produced by the strings may be modified by feedback whereupon special effects can be produced such as a swell effect.

To assist in the playing of background music, it is possible to incorporate in the instrument a play-back device such as a tape recorder.

The conventional frame used in a piano is extremely heavy and is rigid to withstand the considerable force exerted by all the tensioned strings.

This has naturally contributed to the cost of the instrument.

In order to reduce the weight of the piano, it is proposed in the preferred embodiment of the invention that the frame be of tubular construction, comprising tubes not only about its periphery but also a parallel grid.of tubes extending between the strings. Because of this construction each small group of strings is effectively framed separately and there is no longer the need for a long unsupported agraffe to withstand the tension of all the strings. Consequently, the frame members need not be as heavy and as rigid as in the prior art constructions.

Because of the presence of frame members between the strings, the strings cannot be connected directly to the bridges. In the preferred embodiment of the invention, distance pieces are interposed between the strings and the bridges, the latter being conveniently manufactured as an aluminium extrusion. Alumunium lends itself paricularly well to such an application because of its acoustic properties and low density.

In a conventional upright piano, the proximity of the soundboard to the strings prevents any elements of the piano action from being positioned in this space.

The optimum position for the dampers on a piano is immediately opposite the line of impact of the hammers.

In a grand piano, this is readily achieved in that the strings are struck from below whereas the dampers rest on the strings from above under the action of gravity and are raised when the keys are depressed. However upright pianos have hitherto only been overdamped or underdamped, depending on whether the dampers act above or below the line of impact of the hammers and this has generally been acknowledged as inferior.

According to a preferred feature of the invention, the dampers for the strings are arranged in the space between the strings and the soundboards at the same level as the line of the hammers. The dampers may be actuated by means of extensions either of the piano keys or of the wippens, the extensions being arranged to extend between the strings.

The action of the piano may conveniently be mounted on a reinforcement bar connected between the tubes. Because the strings are divided into groups by the tubes reinforcing the frame, a modular approach may be adopted for the design of the action since a group of hammers may be separately formed and assembled on these tubes to strike the strings of the notes in that group.

In this manner, the construction, initial assembly and repair of'the action may be considerably simplified, to reduce the cost of the instrument.

The invention will now be described further, by .way of example, with reference to the accompanying drawings, in which
Figure 1 shows a schematic view of a piano frame.

Figure 2 shows schematically the attachment of the
bridges shown in Figure 1 to soundboards.

Figure 3 shows the mounting of the soundboard for
base notes.

Figure 4 shows the mounting for the other two
soundboards in Figure 2, and
Figure 5 shows the attachment of a string to a
bridge
In Figure 1, there is shown a frame which is made up of tubes. The frame (11) comprises an agraffe 10 to which all the piano strings 12 are connected by the usual arrang-ement for permitting the strings to be tuned. Unlike a conventional frame, the agraffe 10 is supported along its length by means of tubes 14 which form a grid extending between the strings 12. The frame is further strengthened by means of a bar 16 connected both to the outer members of the frame and to the tube 14. The bar 16 may serve to mount the action including the hammers etc. for striking the strings but this is not shown.

Figure 1 also shows schematically the position of three bridges designated 20, 22 and 24 which are connected to the strings in a manner described below. Each string 12 is connected at its two ends to the frame but is stretched over a respective bridge which is not mounted on the frame but on a movable soundboard. The effective length of the string which determines the sound produced when the string is struck is the length between the bridge and the agraffe 10.

The soundboards are rigid boards which are designed not to flex but to vibrate as a rigid body when a string is struck, to amplify the sound produced by the strings 12. The soundboard for the base notes designated 30 in Figures 2 and 3, has the bridge 20 mounted at its lower end while at its upper end it is flexibly mounted on a hinge 31 which is secured to a rigid sound box 33. The sound box 33 is constituted by the casing of the piano. Around its periphery the soundboard 30 is connected by a flexible diaphram 35 to the soundbox 33 so that the box acts as an infinite baffle. Thus the sound waves emanating from the side facing the strings 12 propagates in the forward direction while the sound waves in the oppcsite direction are suppressed.

Because of the substantial weight of the soundboard 30, it is preferable to have a hinge at its upper end but the soundboard is nevertheless capable of oscillating as a rigid body to provide amplificatiion. At its lower end, the sound board 30 is connected by the bridge 20 to several strings and this helps to support it.

In the case of the soundboards 32 and 34 in
Figure 2 which are connected respectively to the bridges
22 and 24, these are mounted by a compliant support 42 which extends around the entire periphery to a sound box
44. This arrangement is shown in Figure 4. The soundboard 32 acts in a manner directly analogous to a
loudspeaker cone.

It will be seen from Figure 1 that each of the bridges crosses one of the tubes 14 arranged between the
strings 12. It is important from the point of view of ensuring the strength of the structure that the-strings and the tubes be in the same plane. To enable the bridge
to be securely mounted to the strings, distance pieces
are provided between the bridges and the strings. This
arrangement is shown in Figure 5 wherein the bridge 20 is seen to be constituted by an aluminium extrusion 60 having a foot 62 secured to the soundboard 30. A tube 64 acting as a distance piece is arranged between the -aluminium extrusion 60 and the string 12.

A single string constituting a note (or two strings of the same note where applicable) are sandwiched between the distance piece 64 and a washer 66 which are in turn secured to the aluminium extrusion by means of a bolt 68 or the like. It is thus seen that the tubes 14 do not interfer with the extrusion 60 which constitutes the bridge and straddle the tubes 14.

Within each sound box 33 and 44, there is arranged a moving coil 70 secured to the respective soundboard and movable relative to a fixed magnet 72 to constitute an inductive transducer which can act either as a pickup or as a drive. When the transducer is used as a drive the soundboard can be operated in the manner of a load speaker to reproduce background music while the sounds produced by striking the strings of the piano may be superimpossed directly onto. the same soundboard.

Alternatively, the inductive transducer may be used as a microphone for recording the music played on the piano or may act as both an inductive pick-up and drive simultaneously. In this case, feed-back circuitry may be employed to modify the natural sound produced by striking the string to achieve swell effects and other special effects. The sound produced may be detected and processed in any manner desired, as known per se, and fed back to the same drive to modify the tone of the piano. As well as producing special effects, this technique- can be used to alter the tone of the piano. If for example the feedback signal is constituted by harmonics of the same note of which the relative amplitude may be electronically selected, the instrument can provide some of the versatility of an electonic organ while retaining the advantages of a mechanical action.

The use of aluminium in the bridge is particularly preferred because of its acoustic properties as well as its rigidity and light weight.

The spacing afforded by the distance pieces 64 and the bridge 60 can enable parts of the action of the piano to be incorporated within this spacing. In a preferred embodiment of the invention (not illustrated) this space is used to mount dampers which are arranged level with the strike line of the hammers. The dampers may be pivoted towards and away from the strings by the action of extensions of the keys or the wippens, these extensions passing between the strings. Apart from providing better damping than in conventional upright pianos, such a construction can also permit a shorter piano to be made since the hammers and the dampers are at-the same level as opposed to the usual upright piano construction which employs dampers arranged above or below the hammers.

An important advantage of having separate soundboards for different notes is that the weight of the soundboards may be better matched to the strings to which they are connected and there is also more flexibility in the positioning of the bridges on the soundboard. The soundboards themselves may be made of any suitable light rigid material and as with loudspeaker cones they may be suitably shaped or strengthened to resist flexing.

It is possible to use the bar 16 to support the piano action and as the strings are divided into groups by the tubes 14 it is possible for the hammer actions to be made in groups or modules which are separately assembled onto the frame.

Claims

AMENDED CLAIMS [received by the International Bureau on 19 September 1983 (19.09.83) original claims 1 to 16 have been replaced by amended claims 1 to 14] 1. A piano comprising a frame, a plurality of taut strings supported on the frame and extending over a bridge and a soundboard coupled to the bridge, wherein the soundboard comprises a rigid member freely suspended relative to the frame by mounting means which enable the rigid member to move towards and away from the frame at least in the region of the bridge, characterised in that the frame (11) of the piano is of tubular construction and includes tubes (14) arranged between the strings (12) and lying in the same plane as the strings (12) and in that the bridges are connected to the strings by way of distance pieces (64).

2. A piano as claimed in claim 1, wherein the piano has a plurality of bridges (20,22,24) each connented to a respective soundboard (30,32,34).

3. A piano as claimed in claim 2, in which at least one (30) of the soundboards is supported relative to a sound box (33) by means of a flexible.hinge arranged at a location remote from the bridge (20).

4. A piano as claimed in claim 2 or 3, in which at least one of the soundboards (32,34) is supported relative to sound box (44) by means of flexible and compliant support.means (42) extending about the entire periphery of the soundboard.

5. A piano as claimed in claims 2, 3 and 4, having a first pivoted soundboard (30) connected to the strings of the base notes, and two further soundboards (32,34) each flexibly supported about its entire periphery.

6. A piano as claimed in any preceding claim, in which an electro-acoustic transducer (70,72) is connected to the or each soundboard (30,32,34).

7. A piano as claimed in claim 6, in which the transducer is connected to act as a microphone.

8. A piano as claimed in claim 6 or 7 in which the transducer (70, 72) is arranged to act as a driver for superimposing on the- vibration of the soundboard caused by the strings a sound derived from an external electrical source.

9. A piano as claimed in claim 8 wherein a play-back device is incorporated in the piano casing and connected to the transducer (70, 72), to enable.play-back of prerecorded background music using the soundboard as a loudspeaker.

10. A piano as claimed in claim 8, wherein the transducer (70,72) is connected to a processing circuit -which- applies electical feedback signals derived by processing signals produced by the struck strings.

11. A piano as claimed in any preceding claim, in which each bridge (20,22,24) is formed as an aluminium extrusion.

12. A piano as claimed in any preceding claim, wherein dampers for damping the strings are mounted in the space between the strings and the sound boards at the same level as the strike line of the hammers.

13. A piano as claimed in any preceding claim, in which the tubes (14) are interconnected by means of a bar (16) also serving to mount the action of the piano.

14. A piano as claimed in claim 13, in which the piano action is formed of a plurality of modules each having a predetermine-d number of hammers associated with the strings arranged between a pair of adjacent tubes (14).