The present invention relates to an upright piano.
Horizontal pianos (grand and table) and upright pianos are known. These pianos differ substantially in that part regarding the action mechanism; in horizontal pianos the hammers move from the bottom upwards, whereas in upright pianos they move forwards and backwards.
Physically, the touch consists of determining the attack transient, i.e. in that apparently chaotic stage which precedes the stationary wave. In the piano the stationary wave comes in the continuation of the sound after striking, the pianist being unable to directly intervene in this continuation. Consequently, determining the attack transient by controlling the modalities of encounter of the hammer with the string is all that the pianist can do to influence the sound quality.
In the upright piano the only one of these modalities which can be decided at the hammer departure is the sound intensity, hence the pianist is only able to control the vibration amplitude, which is determined by the initial launch energy.
To this must be added the fact that the facility to control the sound is further diminished by the action of the springs (the spring 28 of the hammer butt 18 and the spring 27 of the damper 26 in
Hence for clarity the touch must also be defined from a subjective viewpoint, i.e. in the perception of the pianist. Touch control is a feedback process, i.e. a certain muscular action determines a certain sound effect, this influencing in real time the next muscular action, and so on until an automatic process is created, constituting one of the fundamentals of the pianist's technique, i.e. the capacity to give musical meanings to the sound. However this process starts only from a certain threshold (i.e. from a minimum perceptive level), and it can be considered that this threshold is a substantially objective detail, dependent only in certain cases, and only partially, on subjective situations, and that to attain it certain objective physical conditions are necessary which require particular characteristics of the instrument. This means that if the pianist's fingers do not “sense” the hammer because of the limits of the instrument, the ear cannot hear a variation in timbre such as to influence the motory action. Below a threshold defined in this manner, evidently no feedback is possible, which objectively means that the instrument, as it does not possess it, does not enable touch.
This threshold is natural in a grand piano, given that the angular momentum of the hammer is sufficiently high and, as already stated, substantially constant, but in an upright piano it appears to be unattainable. However a solution to this problem exists, based on utilizing a “lens effect”, a perceptive phenomenon by virtue of which the pianist can continue to sense the initial resistance of the lever-hammer until reaching the string or, perhaps more exactly, perceives this resistance as if the angular momentum of the hammer at the moment of striking were the same as that at the start. As a particular study of the causes of this phenomenon has not been possible, it can be assumed that it depends on the reaction time of our perceptions which, both for that regarding hearing (and also sight) and for that regarding the grand musculature, is generally defined as 75/1000 of a second. Hence, touch in an upright piano is probably possible only when the stroke of the hammer 22 has a duration of less than that time, hence making separate perception of the initial angular momentum of the stroke of the lever-hammer 3 from the final momentum impossible, if the final momentum is positive and reaches a perceptible minimum.
The object of the invention is therefore to make it possible to manifest this “lens effect”, which can be achieved only by a coordinated and unitary system of interventions able to increase both the angular velocity and the overall value of the angular momentum of the lever-hammer 3, and to withdraw the barycentre B of this lever from the vertical V through the pin 18 (in the opposite direction to the string 1), for a further necessary increase in the angular momentum. With this coordinated unitary system there is also associated gravity rather than spring operation, both of the return of the hammer 22 and of the action of the damper 26, with the advantage of eliminating, together with the springs 27 and 28, those other elements in the action mechanism action which are not controllable by the pianist.
This object is attained according to the invention by an upright piano as described hereinafter.
Some possible embodiments of the present invention are described hereinafter by way of non-limiting example with reference to the accompanying drawings, in which:
As can be seen from the drawings,
The measurements represented in
The consequences resulting from the interdependence of these values can now be explained in concrete form. If, instead of increasing the weight of the hammer butt at 25 and of the balance hammer at 19, the weight of the hammer 22 were to be reduced until it became 37.5% less than their total weight (i.e. to 4.5 grams), the necessary reduction in the arm B-21 would be likewise achieved together with the consequent increase in angular velocity. The consequences of this hypothesis will be seen hereinafter, which involve a lesser overall value of the angular momentum. In addition it should be noted that in the solution represented in
By way of example, with regard to the hammer butt 18 we propose a construction of light alloy or another material not much heavier than wood, the thickness of which (less than the current 8 millimeters) should be modulated such as to determine the position of the center of gravity according to design choices, and in any event as close as possible to the horizontal O through the pin 21 and to the pin itself (obviously on the opposite side of this pin 21 to the string 1).
That which must remain unvaried is the system of measurements which we have defined in the introduction. In particular, the guiding principle must be the clear perception of the change in sound (as if the sound came alive) which is achieved when this system of measurements is fully realized, and which does not become stable prior to that moment.
The assumption could also be made of a different design for the pieces involved in the dynamics of the hammer 22, but this would involve modifications in the action mechanism which go beyond the framework of the present invention, even though they could constitute a valid application thereof. We would merely mention the fact that acting on the wippen 10 or on the key 4 could be useful in influencing the angular velocity or to compensate the greater weight of the lever-hammer 3. However we consider it necessary, for the effects of touch control in an upright piano, that in the perception of the pianist the resistance of the lever-hammer 3 must always prevail, and in particular that part of the resistance which is determined by the force of gravity. The key 2 and the wippen 10 serve only to launch the hammer 22. It is the hammer which produces the sound, it is the length of its arm which stabilizes the possible launching velocity, and it is only the total weight of the lever-hammer 3 which defines the sound efficiency of the instrument, not the weight of other parts of the instrument (or even less the weight of the muscular masses of the pianist).
Shifting the pin 21 rearwards with respect to the vertical V is one of the essential elements of this invention, and as seen in
In effect, the only piece of the lever 3 in which the necessary horizontal displacement of the center of gravity does not vary, for equal weight and length of the arm B-21, is the hammer 22. Because of this, in
Hence in the particular aspect of the invention illustrated in
As can be seen in this figure, the felt element 41 has at the striking point the same shape and thickness as the hammer 22, but with the weight about halved. The plate 42 and the threaded rod 43 (of magnesium alloy or carbon fibre) enable the felt element to be retained by the former (to prevent rear and lateral dispersions of the thrust at the moment of striking) and the counterweight 46 to be regulated by the latter to shift the center of gravity B rearwards, again with a possible weight reduction compared with the traditional wooden support 40.
The hypothesis of a “lightweight” hammer appears to be in contrast with the idea that satisfactory sound dynamics and volume in an upright piano require a hammer of large weight and dimensions, an idea not without basis in reality. However it remains a fact that providing a hammer 22 of large weight, given its distance from the pin 21, causes a corresponding reduction in the angular velocity of the lever-hammer 3, whereas it is without doubt that the weight which matters is not that of the hammer alone, but the total weight of the lever-hammer 3.
As can be clearly seen in the drawing of
The hammer 22B also solves a problem which was noted during the experimental stage of the present invention: given the very small limits of tolerance in defining the position of the center of gravity B, any repeated filing of the felt elements (usual in the manufacture of the instrument) inevitably causes this center of gravity to advance, and just a few millimeters are sufficient for the piano to lose touch. The ease with which the necessary correction can be made with this new type of hammer is evident.
As an alternative to that proposed heretofore, withdrawal of the barycentre B from the string and from the vertical V through the pin 21 is also possible by forwardly inclining (towards the keyboard) the string 1, together with all the action mechanism. We mention this hypothesis, although protected by a USA patent until June 2012, to express the opinion that a modification of this type could not in itself give an increase in the angular velocity of the lever 3, and hence give a real auditory perception of touch. However if used, to an extent of at least 5°, together with rebalancing of the weights within the scope of the lever-hammer 3 proposed in the present invention, it would solve the problem of horizontally shifting the center of gravity B, as an alternative to the aforedescribed solutions.
In the introduction it was stated that the spring problem was among those constituting an obstacle to the achieving of touch, which the invention proposes to solve. We would note that in the solution proposed in
The first drawing (
In the drawing B of
Again in
Both in the arrangement of 5B and in that of 5C an adequate space is required to enable the necessary movement of the counterweight 35 or 35A. In large form pianos the problem does not exist, the pilot 8 being longer than it appears in
From what has been stated, it is clear that the action mechanism of the upright piano modified according to the invention presents evident advantages, and in particular:
gives touch to an upright piano,
defines a system of interdependent measurements to achieve this result in a manner which is not random or intuitive, but instead based on objective elements,
enables the proposed basic result to be achieved by different design solutions obtainable by combining together the different proposed solutions in various degrees,
with the different gravitational arrangement of the lever-hammer 3 it gives the pianist not the perception of any type of resistance, but the clear sensation of lifting the weight of the hammer 22 and of being able to manoeuvre it exactly as in a grand piano,
with the high angular momentum of the lever-hammer 3 the sound possibilities of the instrument, which can be controlled with greater precision, are more greatly exploited,
the use of the solution comprising the variable barycentre hammer 22B offers those facilities for precise hammer regulation which do not exist in current pianos,
it enables the lever-hammer 3 to return by force of gravity alone, making it possible to avoid those negative effects on touch due to the use of the spring 28,
it enables the sound to be dampened by gravitational force, hence making it possible, given the elimination of the spring 27, to provide total performance control, including sound closure, without substantially modifying the current operating system for the damper 26.
Number | Date | Country | Kind |
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VE2010A0028 | Jun 2010 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2011/001321 | 6/10/2011 | WO | 00 | 12/3/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/154825 | 12/15/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
851001 | Doyle | Apr 1907 | A |
896763 | Schimmel | Aug 1908 | A |
2123736 | Klein | Jul 1938 | A |
2273789 | Prevost | Feb 1942 | A |
2436875 | Socin | Mar 1948 | A |
2844984 | Dasenbrook et al. | Jul 1958 | A |
3100416 | Roehrig | Aug 1963 | A |
4854211 | Tanaka et al. | Aug 1989 | A |
4879939 | Wall | Nov 1989 | A |
5022302 | Guyon | Jun 1991 | A |
5042354 | Trivelas et al. | Aug 1991 | A |
5583306 | Hayashida et al. | Dec 1996 | A |
5679914 | Niitsuma | Oct 1997 | A |
6054641 | Inoue | Apr 2000 | A |
6248943 | Inoue | Jun 2001 | B1 |
6965070 | Wenjun | Nov 2005 | B2 |
8294009 | Muramatsu et al. | Oct 2012 | B2 |
8389833 | Muramatsu et al. | Mar 2013 | B2 |
20100192748 | Inoue | Aug 2010 | A1 |
20110232456 | Muramatsu et al. | Sep 2011 | A1 |
20130112060 | Pancino | May 2013 | A1 |
Number | Date | Country |
---|---|---|
0689182 | Dec 1995 | EP |
Number | Date | Country | |
---|---|---|---|
20130112060 A1 | May 2013 | US |