DE4414100A1 - Damping mechanism unit for upright piano - Google Patents

Abstract

The mechanism uses friction at the transition between the damper spoon and the damper arm. The mounting (C) of the damper arm (17b), the mounting (B) of the lever member (11c), and the contact point of the damper spoon (31b) lie for this purpose on a straight line on the damper arm.On the damper arm is formed a lug (17ba), and a lever member cartridge (12d) is obliquely fitted. The hinge axis (B") of the cartridge is nearer to one end extension of the damper arm than the middle of the cartridge path between the fastening screw head (12B) and the mechanism beam (13a).

Description

The invention relates to a damper mechanism for a hammer instrument according to the preamble of claim 1 as well as one equipped with such a mechanism Hammer instrument.

Hammer instruments have a keyboard with side by side lying keys, each of which has a mechanism whose Limbs are made of solid wood, a hammer is operated. Becomes a button is pressed, the hammer belonging to it is turned a string moves and produces a sound when it strikes the String hits.

When the button is released, the sound generated in this way should a certain path of those returning to their starting position Button can be dampened again. This fulfills the task Damping mechanism of the hammer instrument.

The invention deals with the improvement of the damper mechanism.

Fig. 1 shows on a scale of 1: 2 the construction of the damper mechanism, which has been built exclusively for decades, on a single link without the associated hammer mechanism. Further individual elements are constructed in the same way and are one behind the other in relation to the drawing level.

On the keyboard frame 1 , the balance beam 2 , which carries the upstanding pin 3, is fastened approximately in the middle of this frame. On the balance bar 2 , the key 4 is tiltably mounted around this pin in the drawing plane. The pivot point of the bearing is labeled A. Key 4 is struck at point P. There, in the keyboard frame 1, the key guide pin 5 projecting into an elongated hole of the key 4 is fastened, on which the felt disc 6 is inserted. Under the end of the stop P₁ the button 4 , the felt pad 7 is glued to the keyboard frame 1 . The key carries at its end opposite the stop P 1 the lead weight 8 and, closer to the balance beam, the set screw 9 , which has a convex surface. The felt 10 , which is glued onto the lifting member 11 from below, rests on this adjusting screw. This lifting member is rotatably mounted in the capsule 12 in the plane of the drawing. The hinge axis bears the designation B. The capsule 12 is screwed onto the mechanical beam 13 with the screw 12 A. It runs approximately perpendicular to key 4 . Between the capsule 12 and the mechanical bar 13 is the notch wire 14 , which runs half in a notch of the mechanical bar 13 and a notch of the capsule 12 . This wire causes the capsule 12 to align at right angles to the mechanical beam 13 when it is screwed on. The protrusion G is formed on the mechanical beam 13 above the capsule 12 .

The further structure is explained with reference to FIG. 2, which shows an enlarged detail from FIG. 1. The lifting member 11 is designed as a two-armed lever, the long arm of which extends from the hinge axis B to the adjusting screw 9 , while the short arm points in the opposite direction. In this short arm of the lifting member 11 of the elevating member 11 is attached an elongate uprising element 15 perpendicular to the course, which is referred to as a damper spoon. The damper spoon consists of a wire that is bent into a spoon shape at its upper end. This spoon holds in the idle state of the arrangement with its covex side a small distance from the damper felt cloth 16 which is glued to the damper arm 17 . The damper arm 17 is designed as a two-armed lever and is rotatably mounted in the damper capsule 18 . The hinge axis is called c. The damper capsule 18 is screwed onto the side of the mechanical bar 13 pointing away from the button 4 and extends perpendicular to the capsule 12 . It is aligned by the notch wire 19 in the same way as described for the notch wire 14 . The damper spring 20 is fastened in the damper capsule 18 by being wound around an axis running perpendicular to the plane of the drawing. The spring base point thus created bears the designation D. The short arm of the damper spring 20 presses against the damper capsule 18 , its long arm is rounded at its end, presses against the upper lever arm of the damper arm 17 and runs in a graphitized groove 17 a thereof. The damper spring 20 causes the damper arm 17 to rotate counterclockwise about the hinge axis c.

At the upper end of the upper lever arm of the Dämpferarms 17 of the wire 21 is fastened, onto which the dampers doll 22 is screwed, on which on which the string is glued 23 facing string of the damper 22 a which in turn on its side facing the string 23 string with the soft Damper felt 24 is occupied. This damper felt is pressed by the action of the spring 20 against the string 23 and dampens possible vibrations thereof.

In a hammer instrument, there should be the possibility that the dampers of all the individual links can be lifted off independently of the key position. For this purpose, the damper rod 25 , which runs transversely to the plane of the drawing, is located in an indentation of the mechanical beam 13 . This damper rod carries the extensions 26 and 27 extending transversely to the rod outside the plane of the drawing. The extension 26 is rotatably mounted on the mechanical beam 13 . The hinge axis bears the designation F. The damper rod 25 can be pivoted about the hinge axis F in the plane of the drawing. The rod 28 , which can be moved up and down in the bearings 29, is located under this extension in the pivoting plane of the extension 27 . The rod 28 is actuated via a pedal, not shown. Compared to the pedal rod 25 , the damper felt cloth 16 runs over the set screw 30 , which is designed as a grub screw. The set screw 30 is screwed through the damper arm 17 .

The arrangement works as follows:. If in Figure 1, the button 4 depressed by the force P, the button 4 tilts in a clockwise direction about the pivot point A is limited by its passage through the felt. 6 The other end of the button 4 is stuck, with it the adjusting screw 9 . This acts on the lifting member 11 via the felt 10 , rotating it about the axis B counterclockwise.

The process is further described with reference to FIG. 2. By rotating the lifting member 11 , the upper end of the damper spoon 15 moves to the left, strikes the damper felt cloth 16 and sets the damper arm 17 in motion. This rotates clockwise around the axis C. Thus, the damper 22 a attached to it via the wire 21 is moved away from the string 23 , the damper felt 24 is no longer in contact with the string 23 and this can swing freely. The damper felt is lifted off the string when the key is pressed halfway, i.e. when key 4 is pressed halfway.

In Fig. 1, the key 4 at the point P₁ released, ie the force P₁ is omitted, the weight 8 lowers the left side of the key 4th This lowers the set screw 9 and with it the lifting member 11 due to its own weight, ie it rotates clockwise about the axis B. By this rotation, the free end of the damper spoon 15 moves to the right and releases the damper arm 17 . The damper spring 20 rotates the damper arm 17 counterclockwise around the axis C, whereby the damper 22 a is moved against the string 23 . The damper felt 24 is finally pressed against the string 23 and any vibration of this string is prevented.

Adjusting the distance from the damper spoon to Damper felt cloth is made by bending the damper spoon.

The lifting of all damper members by the damper rod 25 works as follows: If the pedal (not shown) is pressed, the rod 28 moves upwards in the bearings 29 . It abuts the extension 27 and turns the pedal rod 25 clockwise around the axis F. The pedal rod 25 thus moves against the damper arm 17 and finally rotates it clockwise around the axis C. The damper 22 a lifts the damper felt 24 off the string 23 . At which distance the damper rod 25 begins to lift the damping, ie the lifting point of the damping can be set using the adjusting screw 30 .

The known construction has the following shortcomings:

1) Friction at the transition from damper bucket 15 to damper felt 16

FIG. 3 shows, in a detail from FIG. 2, the relationships at the axis of rotation B, the axis of rotation C and the transition from the damper spoon 15 to the damper felt cloth 16 . As seen from Fig. 3, the lifting member 11 and the damper spoon 15 mounted thereon rotate about the axis B. The free end of the damper spoon 15 describes b the circular arc whose center constitutes the axis B. The end of the damper arm 17 opposite the damper spoon describes the circular arc c, the center point of which represents the axis C.

Both arcs intersect at the level of the damper spoon 15 . Their tangents through the point of intersection form the angle alpha to each other. If the angle alpha were zero, there would be no friction path of the damper spoon on the damper felt cloth during the movement. A typical value for the angle alpha is 35 degrees. This results in a not inconsiderable friction path and there are friction losses when the damping mechanism is actuated. Second, as the applicant has seen in several older pianos, holes are rubbed into the damper felt cloth over time, making the mechanics unplayable. The lower the mechanical construction, the greater the angle alpha.

2) Friction of the damper spring 20 on the damper arm 17

FIG. 4 shows, in a further detail from FIG. 2, the conditions at the axis of rotation C, the spring base point D and the bearing point E of the damper spring 20 on the damper arm 17 .

Points C, D and E form a triangle, which is shown in FIG. 5. Since the damper spring 20 can slide in the groove 17 a of the damper arm 17 , the distance CE is variable. Now, the damper arm 17 rotates clockwise around the axis c, as shown in Fig. 5, the support point E to point E '. The following applies: CE ′ <CE.

During this movement, the damper spring 20 straightens. The route DE, which was previously assumed to be constant, is extended to route DE '. This also drives the spring's point of contact upwards.

3) progression of the damper spring 20

Fig. 6 shows the upper part of the damper arm 17 , the damper spring 20 and the damper capsule 18. The damper spring 20 is shown in the relaxed state by the dashed line leading to the point E ''; in the idle state by the solid line leading to point E and in the raised state by the dashed line leading to point E '. In the state in which the damper spring ends at point E ', it will exert greater pressure on the damper arm 20 than in the idle state. Such an increase in strength is due to the button and disturbs the mood of the fingers.

According to Hook's law, the relative increase in force of the damper spring 20 is the quotient of the distance EE ', which is called the tension path, to the distance EE'', which is called the preload path. It is advisable to have the largest possible preload path. This is limited by the quality of the spring material. The spring is designed to be curved, as this allows a larger preload. A stronger bend, however, leads to a larger spring extension and thus to an increase in the friction path of the spring in the groove 17 a.

 Great increase in game severity when lifting the damping at the bass

The strings that produce the low notes have a considerable vibration amplitude. If the damper felt 24 now lies on the vibrating string, the vibration passes through this felt and the damper 22 a and the damper doll 22 a vibrate with it. In order to achieve a quick damping of the string 23 , the damper spring 22 must be designed particularly strong. The force required to depress the key, the level of play, rises sharply at the lift-off point of the damping, ie when the key is pressed halfway.

5) Friction at the transition from the button to the lifting link

If one places a straight line in FIG. 1 through the axis of rotation B of the lifting member and the fulcrum point A of the key 4 , this straight line will intersect the contact point of the adjusting screw 9 on the felt 10 . The turning circles of the key 4 and the lifting member 11 touch tangentially at the transition point. In contrast to the shortcoming described under point 1), the friction path is minimized. Despite the optimal calculation, residual friction occurs, the greater the flatter the straight line mentioned.

Extent of the described interference effects:

Point 1): The difference in the torque of the lifting member 11 about the axis B, which was necessary to lift the damper off the string, and the torque in the opposite rotation was 10% for a model mechanism with a larger overall height. The friction of the damper spring on the damper arm was switched off.

Point 2): The friction losses were about 1/3 of the Friction losses from point 1).

Point 3): The applicant submitted a 10% damper progression measured.  

Item 4): This increase was made by the applicant in modern Pianos that value a quick dampening of tones lay, felt as disturbing, but not measured.

Point 5): Under the same test conditions as in point 1 10% friction loss.

The disturbing effects of points 1), 2) and 5) become all the greater, the lower the height of the mechanics.

It is an object of the invention to eliminate the interference effect described under point 1). The invention is based on the idea of placing the axis B, in which the lifting member is mounted, the axis C, in which the damper arm is mounted, and the point of contact of the damper spoon on the damper arm or the damper felt cloth attached thereon, more precisely, to decrease the angle alpha from FIG. 3 as far as possible to the value zero. This eliminates the friction path of the damper spoon against the damper arm. This idea is brought to life by either moving the axis B closer to an imaginary extension of the damper arm 17 by an inclined course of the lifting member capsule, or at the point at which the damper spoon 15 touches the damper arm 17 or the damper felt cloth 16 fastened thereon, a nose facing the mechanical beam 13 is formed or attached to the damper arm. Both implementations can be combined with one another according to the invention.

Another object of the invention is that under point 2) cancel the described interference effect. This will be a Train transmission from the damper spring to the damper arm or one Extension of the damper arm selected using flexible material.

Another object of the invention is that under point 3) cancel the described interference effect. For this, the Damper spring curved in a serpentine shape.  

Another object of the invention is that under point 4) cancel the described interference effect. This is the damper or the damper doll, especially in the limbs that dampen deep strings, made of heavy material, excellent Metal, especially brass, made or on the damper or the damper doll applied heavy material. Thereby the vibrating mass increases and the damper spring can be interpreted weaker.

Another object of the invention is that under point 5) cancel the described interference effect. This will be a Gear transmission selected.

Show it:

Fig. 1, the overall view of the standard design of the damper mechanism,

Fig. 2 shows a detail from Fig. 1,

Fig. 3, the movement conditions at the point of contact of the damper spoon on Dämpferfilztuch,

Fig. 4 shows the spring mechanism of the damping,

Fig. 5, the movement conditions at the point of contact of the damper spring on the damper,

Fig. 6 shows the conditions for the evaluation of the degree of damping progression,

Fig. 7 shows a first embodiment of the inventive concept

Fig. 8 shows a second embodiment of the inventive concept

Fig. 9 shows a third embodiment of the inventive concept

Fig. 10 shows a first embodiment of a damper spring of the invention,

Fig. 11 shows a second embodiment of a damper spring of the invention,

Fig. 12 shows a third embodiment of a damper spring of the invention,

FIG. 13 rotated by 90 degrees view of Fig. 12,

Fig. 14 shows a further embodiment of a Dämpferarms invention,

Fig. 15 a transition from the button to the lifting member according to the invention.

Fig. 16 complaints for the damper in different versions.

Fig. 7 shows a first embodiment. The lifting member capsule 12 b, in which the lifting member 11 a 'is rotatably supported by the axis B', is angled in itself. Your fork part, which carries the axis B ', runs at an obtuse angle to the part with which the lifting member capsule 12 b is attached to the mechanical beam 134 . The lifting member capsule 12 b is fastened to the mechanical beam 13 with the screw 12 A. The dashed line 12 ba marks the boundary of the solid wood part of the capsule 12 b to the capsule-shaped part. This capsule-shaped part shows in the direction of the lifting member 11 a 'and the string 23 as in Fig. 2nd

This obtuse-angled shape of the lifting member capsule 12 b ensures that the axis B 'is closer to an imaginary extension of the damper arm 17 a than the lifting member capsule 12 b at its attachment point on the mechanical beam 13 , more precisely than the center of the strength of the lifting member capsule, the is located between the head of the screw 12 A and the support of the lifting member capsule 12 b on the mechanical beam.

The lifting member 11 a 'is recessed parallel to the capsule-shaped part of the capsule 12 b. The boundaries of the recess 11 from 'and 11 ac' run a few mm from the lifting member capsule 12 b. The end of the lifting member 11 a 'is pulled up at the point where the damper spoon 31 is attached, the damper spoon. The resulting nose is called 11 ad '. The damper spoon is 31 is squeezed into a spoon shape at its free end.

The convex side of this spoon shape lies opposite the damper felt cloth 16 a, which is pulled over the damper arm 17 a.

On the damper arm 17 a, at the point opposite the spoon-shaped part of the damper spoon 31 , there is a projection pointing towards it, which is preferably designed as a nose 17 on the damper arm 17 a. The damper arm 17 a is rotatably mounted in the capsule 18 with the axis C. The axes B 'and C, and the contact point of the damper spoon 31 on the damper felt cloth 16 a are exactly or approximately on a straight line, which is entered at its ends under the designation L.

Instead of the damper felt cloth, the damper spoon 31 can also be covered with soft material. Then the damper spoon coated in this way directly touches the damper arm.

Function: If the lifting member rotates with the axis B 'in the lifting member capsule 12 b counterclockwise, the path of the spoon-shaped free end of the damper spoon 31 runs perpendicular to the straight line L. With further rotation, the damper spoon 33 moves the nose over the damper felt cloth 16 b 170 b at the lower end of the damper arm 17 b also perpendicular to the straight line L. Along the straight line L, no movement occurs through either of the two links. It follows that the friction path of the damper spoon 31 on the damper felt cloth 16 a disappears.

Fig. 8 shows a variant. The lifting member capsule 12 c, which is fastened to the mechanical beam 13 with the screw 12 A, is designed to be double angled in the form of an obtuse angle "Z". The dashed line in the Hegegliedkapsel 12 c shows the transition from the forks to the solid wood part of the lifting link capsule. The lifting member 11 b, which is mounted with the axis B 'in the lifting member capsule 12 c, is recessed around the lifting member capsule 12 c, the boundaries of the recess not running parallel. The end of the lifting member 11 b, which receives the damper bucket 31 a, is carried out as in the standard construction. The damper spoon 31 a is similar to the damper spoon 31 , but extends at an acute angle to the lifting member 11 b.

FIG. 9 shows a further variant in which the nose on the damper arm is enlarged. The mechanical beam 13 a is recessed obliquely for receiving the lifting member capsule 12 d. The nose G of the mechanical beam 13 from FIG. 2 is omitted. An imaginary straight extension of the mounting surface of the mechanical beam 13 a for the lifting member capsule 12 d intersects with the edge of the mechanical beam, which points away from the damper arm 17 b or its imaginary extension. The lifting member capsule 12 d is preferably straight in shape. The dashed line shows the boundary between the solid material part and the fork part. This limit may be executed parallel to the c also pointing to the action bracket side of the elevating member. 11 The angle which the lifting member capsule 12 d with the long lever arm of the lifting member 11 c, which appears in Fig. 9 to the right of the axis B '', is a sharp. As a result, the axis B '' is closer to an imaginary extension of the damper arm 17 b than the center of the capsule 12 d between the head of the screw 12 b, with which it is fastened on the inclined surface of the mechanical beam 13 a, and the contact surface on the mechanical beam 13 a.

The circular recess on the lifting member 11 c about the axis B is preferably of larger diameter than in the standard construction. Otherwise, the lifting member 11 c is preferably designed like the lifting member 11 . The mechanical bar 13 a is formed without the projection G.

Its support surface for the lifting member capsule 12 d runs, as said, at an angle to its other course. These two measures create space for a larger nose 17 ba on the damper arm 17 b, which is covered with the damper felt cloth 16 b. This larger nose 17 ba on the damper arm ensures that the joints B '' and C and the point of contact of the damper spoon 31 b on the damper arm come to a straight line. The nose 17 ba of the damper arm 17 b is delimited in FIG. 9 from the rest of the damper arm 17 b by a line which optionally designates a smaller extent of this nose transverse to the plane of the drawing than the rest of the damper arm 17 b. This makes the screw 12 B, with which the lifting member capsule 12 d is screwed to the mechanical beam 13 a, more easily accessible.

The variant shown in FIG. 9 reduces the strength of the mechanical beam 13 a compared to the mechanical beam 13 from FIG. 2 at the point at which the lifting member capsule 12 d is screwed onto the mechanical beam. This variant is particularly suitable for mechanical beams that are made of metal.

Question Figs. 7, 8 and 9 show constructions in which the axis B or B 'and B'', the axis C and the contact point of the damper spoon on the damper or the glued thereon Dämpferfilztuch which three places the "three Points "should be placed exactly on a straight line. However, the friction of the transition is already reduced by intermediate solutions between the standard construction and the construction shown in FIGS. 7, 8 and 9. The "three points in question" do not have to lie exactly on a straight line. Such interim solutions are included in the application.

It is also possible to go beyond the goal and convert the obtuse angle which the "three points in question" form in the standard construction into an angle that exceeds 180 degrees. As long as the angle is close to 180 degrees, the friction behavior improves. This takes place by further displacement of the axis B 'ind Fig. 7 and Fig. 8 and the axis B in Fig. 9 in the direction towards the not illustrated in these figures string 23rd This can also be done by further enlarging the nose 17 or 17 ba. Such a solution is also included in the application.

Are included in the invention transitions between the ba in whippen flange shapes shown in Figure 9 and fastening bevels on action bracket Fig. 7, Fig. 8 and Fig., As well as intermediate forms between the large nose 17 on the damper 17 b and the shape of the Dämpferarms 17 in FIG. 2. The nose 17 on the damper arm 17 a or the nose 17 ba on the damper arm 17 can be formed as a projection on the damper arm or consist of a part that is applied to the damper arm or in a dowel or a screw, generally made of material that in a recess in the damper arm is inserted.

Fig. 10 shows a frictionless construction of the damper spring. Not only the damper wire 21 is fastened to the upper end face of the damper arm 17 i, but also the excellently double-angled spring-loaded transmission wire 40 . This is bent into a hook at the free end. In this hook, the ring 41 is suspended, which is made of flexible material, especially plastic. The other end of the ring 41 engages in the hook-shaped curved free end of the damper spring 20 a, which is fastened like the damper spring 20 in the damper capsule 18 . Instead of the ring 41 , a thread loop knotted with the spring-loaded transmission hook 40 can also be used.

Fig. 11 shows a low-progression construction of the damper spring. The damper spring 20 b is fixed at the base D in the capsule 18 and is led up in serpentine windings which lie in the plane of the drawing. The turns can also lie transversely to the plane of the drawing or be designed as screw turns. The free end of the damper spring 20 b is suspended in the ring 41 , the other end of which is suspended in the hook-shaped end of the damper cable transmission hook 40 a. The damper cable transmission hook is designed as a triple angled wire, which is inserted into a bore in the longitudinal side of the damper arm 17 j and fastened therein. This construction is particularly suitable for upgrades.

Fig. 12 shows a low-progression damper spring which runs on the side of the damper arm facing away from the mechanical beam 13 , 13 a. The damper spring 20 c runs between the string 23, not shown, and the damper arm 17 k. It is bent back and forth across the plane of the drawing in a serpentine manner, which bend appears in FIG. 13, which FIG. 12 shows rotated by 90 degrees. The free end of the damper spring 20 c is suspended in the cord loop 42 whose ends are glued into a top on the front side of the Dämpferarms 17 k projecting nose 17 ka. The cord loop 42 is drawn in perspective and runs in front of and behind the damper wire 21 in FIG. 12.

The lower end of the damper spring 20 c runs in a groove which is drawn on one side of the damper capsule 18 a around its rounded end and the side which rests on the mechanical beam 13 , 13 a. The damper spring 20 sits at its end in a bore of the capsule 18 a, which is located on the hinge side opposite end of the capsule 18 a.

The advantage of this construction is that the wire of the damper spring 20 b is much longer than that of the damper spring 20 or 20 a, can also be made longer than that of the damper spring 20 b. The spring material is subjected to bending and torsion. With the same spring material, a larger preload of the damper spring is possible.

FIG. 14 shows a damper arm in which the damper arm itself and the projection for the pull cord for the damper spring are made from one piece, which has the designation 17 m and is rotatably mounted in the axis C as described above. The projection 17 ma is less strong across the plane of the drawing than the damper arm 17 m, so as not to come into conflict with the hammer mechanism (not shown). In the projection 17 ma at least one groove is made, which is shown in broken lines. In this groove, the ends of the cord loop 41 a are glued into which the damper spring 20 a is suspended.

Fig. 15 shows a smooth transition from the button to the lifting link, which is designed as a wheel transition. In the key 4 a, as is known, the piece of hardwood 43 is glued, which gives the set screw 9 a a permanent fit. The piece of hardwood 43 has at the end of the key 4 a a projection 43 a pointing away from the key, on the parallel to the course of the key 4 a the end face of the felt 44 is glued, which rests on the screw head of the adjusting screw 9 a. The side of the set screw 9 a pointing away from the button 4 a is designed as a spherical cap, either with the same radius as with the set screw 9 or with a larger radius up to a flat surface. On the side of the felt 44 pointing away from the button 4 a, the wheel 45 rests on this felt, which is rotatably mounted in the extension member 11 a in the extension of the axis of the adjusting screw 9 a. The bearing axis located in the extension of the axis of the adjusting screw 9 a bears the designation H.

The wheel 45 runs in a slot with a circular saw blade of small diameter in the lifting member 11 a, the boundary line of which carries the designation 11 from. The side of the lifting member 11 a pointing to the button 4 a is designed as a curve, but curved lines are also possible. The lifting member 11 a is mounted like the lifting member 11 in the lifting member capsule 12 , 12 a.

When you press the button and the associated rotation of the lifting member 11 a about the axis B, the wheel 45 rotates so that no friction occurs at the transition to the lifting member.

Fig. 16 shows embodiments of the weighting of the damper. Fig. 16a shows a normal damper construction, in which the damper doll 22 'or the damper 22 a' or both are made of heavy material, preferably metal, instead of wood. Fig. 16b is an enlarged damper doll 51, which is made of heavy material. Fig. 16c shows the damper 22 a patch weights 52nd

Claims (16)

1. Damping mechanism unit for an upright hammer instrument with

• - a mechanical beam ( 13 , 13 a) of the hammer instrument,
• - A lifting member ( 11 , 11 a, 11 a ', 11 c) which can be actuated by the button ( 4 , 4 a) assigned to a string ( 23 ) and which is in a mechanical screw ( 13 , 13 a) of the hammer instrument with a screw ( 12 A, 12 B) fastened first capsule ( 12 , 12 b, 12 c, 12 d) is rotatably mounted about a first axis (B, B ′, B ′ ′),
• - A damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) pointing at one end to an imaginary extension of the lifting member, which in a second capsule ( 18 ) also fastened to the mechanical beam ( 13 , 13 a) is rotatably mounted about a second axis (C) perpendicular to the longitudinal direction of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and parallel to the first axis (B, B ′, B ′ ′), at its other end a damper element ( 21 a, 22 , 24 ) can be fastened via a wire ( 21 ),
• - A damper spring ( 20 , 20 a, 20 b, 20 c), which loads the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and thus the damper element ( 21 a, 22 , 24 ) presses against the string to be damped ( 23 ),
• - In the lifting member ( 11 , 11 a, 11 a ', 11 c) mounted rod-shaped actuating element ( 5 , 31 a, 31 b), which is designed and arranged such that when the button ( 4 ) triggers a rotary movement of the lifting member ( 11 , 11 a, 11 a ′, 11 c) around the first axis (B, B ′, B ′ ′) of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) around the second Axis (C) is rotated such that the damper element ( 21 a, 22 , 24 ) is lifted off the string ( 23 ),

characterized in that the hinge axis (B ′, B ′ ′) of the first capsule ( 12 b, 12 c, 12 d) is closer to an imaginary extension of one end of the damper arm ( 17 a, 17 b) than the center the thickness of the first capsule ( 12 b, 12 c, 12 d) at the point at which the first capsule ( 12 b, 12 c, 12 d) is attached to the mechanical beam ( 13 , 13 a), "thickness of the first Capsule "means the distance that the first capsule ( 12 b, 12 c, 12 d) attached to the mechanical beam occupies between the head of the fastening screw ( 12 A, 12 B) and the mechanical beam ( 13 , 13 a). 2. Damping mechanism unit of a hammer instrument with

• - a mechanical beam ( 13 , 13 a) of the hammer instrument,
• - a key ( 4 , 4 a) assigned to a string ( 23 ),
• - One of the strings ( 23 ) assigned button ( 4 , 4 a) actuated lifting member ( 11 , 11 a, 11 a ', 11 c), which in one on the mechanical beam ( 13 , 13 a) of the hammer instrument with a screw ( 12 A, 12 B) fastened first capsule ( 12 , 12 b, 12 c, 12 d) is rotatably mounted about a first axis (B, B ′, B ′ ′),
• - A damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) pointing at one end to an imaginary extension of the lifting member, which in a second capsule ( 18 ) also fastened to the mechanical beam ( 13 , 13 a) is rotatably mounted about a second axis (C) perpendicular to the longitudinal direction of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and parallel to the first axis (B, B ′, B ′ ′), at its other end a damper element ( 21 a, 22 , 24 ) can be fastened via a wire ( 21 ),
• - A damper spring ( 20 , 20 a, 20 b, 20 c), which loads the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and thus the damper element ( 21 a, 22 , 24 ) presses against the string to be damped ( 23 ),
• - In the lifting member ( 11 , 11 a, 11 a ', 11 c) mounted rod-shaped actuating element ( 5 , 31 a, 31 b), which is designed and arranged such that when the button ( 4 ) triggers a rotary movement of the lifting member ( 11 , 11 a, 11 a ′, 11 c) around the first axis (B, B ′, B ′ ′) of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) around the second Axis (C) is rotated such that the damper element ( 21 a, 22 , 24 ) is lifted off the string ( 23 ),

characterized in that the hinge axis (B ′, B ′ ′) of the first capsule ( 12 b, 12 c, 12 d) is closer to an imaginary extension of one end of the damper arm ( 17 a, 17 b) than the center the thickness of the first capsule ( 12 b, 12 c, 12 d) at the point at which the first capsule ( 12 b, 12 c, 12 d) is attached to the mechanical beam ( 13 , 13 a), "thickness of the first Capsule "means the distance that the first capsule ( 12 b, 12 c, 12 d) attached to the mechanical beam occupies between the head of the fastening screw ( 12 A, 12 B) and the mechanical beam ( 13 , 13 a). 3. Damping mechanism unit of a hammer instrument with

• - a mechanical beam ( 13 , 13 a) of the hammer instrument,
• - A lifting member ( 11 , 11 a, 11 a ', 11 c) which can be actuated by the button ( 4 , 4 a) assigned to a string ( 23 ) and which is in a mechanical screw ( 13 , 13 a) of the hammer instrument with a screw ( 12 A, 12 B) fastened first capsule ( 12 , 12 b, 12 c, 12 d) is rotatably mounted about a first axis (B, B ′, B ′ ′),
• - A damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) pointing at one end to an imaginary extension of the lifting member, which in a second capsule ( 18 ) also fastened to the mechanical beam ( 13 , 13 a) is rotatably mounted about a second axis (C) perpendicular to the longitudinal direction of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and parallel to the first axis (B, B ′, B ′ ′),
• - One with the other end of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) via a wire ( 21 ) connected damper element, which from the damper manikin ( 22 , 22 ', 51 ), the damper ( 22 a, 22 a ′, 50 ) and the damper felt ( 24 ),
• - A damper spring ( 20 , 20 a, 20 b, 20 c), which loads the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) and thus the damper element ( 21 a, 22 , 24 ) presses against the string to be damped ( 23 ),
• - In the lifting member ( 11 , 11 a, 11 a ', 11 c) mounted rod-shaped actuating element ( 5 , 31 a, 31 b), which is designed and arranged so that when the button ( 4 ) triggers a rotary movement of the lifting member ( 11 , 11 a, 11 a ′, 11 c) around the first axis (B, B ′, B ′ ′) of the damper arm ( 17 , 17 a, 17 b, 17 i, 17 j, 17 k) around the second Axis (C) is rotated such that the damper element ( 21 a, 22 , 24 ) is lifted off the string ( 23 ),

characterized in that the hinge axis (B ′, B ′ ′) of the first capsule ( 12 b, 12 c, 12 d) is closer to an imaginary extension of one end of the damper arm ( 17 a, 17 b) than the center the thickness of the first capsule ( 12 b, 12 c, 12 d) at the point at which the first capsule ( 12 b, 12 c, 12 d) is attached to the mechanical beam ( 13 , 13 a), "thickness of the first Capsule "means the distance that the first capsule ( 12 b, 12 c, 12 d) attached to the mechanical beam occupies between the head of the fastening screw ( 12 A, 12 B) and the mechanical beam ( 13 , 13 a). 4. Damping mechanism unit according to claim 1, characterized in that the first capsule ( 12 b, 12 c) is designed in a self-angled shape, so that the part of the first capsule ( 12 b, 12 c), its attachment to the mechanical beam serves, and at least a portion of the fork part of the first capsule ( 12 b, 12 c) form an obtuse angle. 5. Damping mechanism unit according to claim 1, characterized in that an imaginary straight extension of the bearing surface of the capsule ( 12 d) on the mechanical beam ( 13 a) from the damper arm ( 17 , 17 a, 17 b) facing away from the edge of the mechanical beam ( 13 a) or an imaginary extension of this edge cuts. 6. Damping mechanism unit according to claim 1, characterized in that the damper arm ( 17 , 17 a, 17 b) at the point opposite the rod-shaped actuating element ( 31 , 31 a, 31 b) with one to the mechanical bar ( 13 , 13 a ) pointing projection ( 17 ab, 17 ba) is provided, which preferably consists of material applied to the damper arm ( 17 ) or of the material of the damper arm ( 17 a, 17 b), or preferably in a bore-shaped recess in the damper arm, preferably as a dowel or screw is attached. 7. Damping mechanism unit according to claim 1, characterized in that between the damper spring ( 20 a, 20 b) and one end of the damper arm ( 17 i, 17 j, 17 m) a two-part spring force transmission member is attached, one part ( 40 , 40 a, 17 ma) consists of solid material and is firmly connected to the damper arm ( 17 i, 17 j, 17 m) and the other part of which is a movable connection from the free end of one part ( 40 , 40 a, 17 ma) to the damper spring ( 20 a, 20 b), preferably by a cord-shaped element ( 41 ) which is suspended in the preferably curved end of one part ( 40 , 40 a, 17 ma) of the two-part spring force transmission member. 8. Damping mechanism unit according to claim 7, characterized in that one part of the two-part spring force transmission member from a projection ( 17 ma) of the damper arm ( 17 m) or in the damper arm ( 17 i, 17 j) used wire-shaped element ( 40 , 40 a ) consists. 9. Damping mechanism unit according to claim 1, characterized in that the damper spring ( 20 b) extends in serpentine lines which lie in the tilting plane of the damper arm ( 17 j). 10. Damping mechanism unit according to claim 1, characterized in that in the second capsule ( 18 a) attached damper spring ( 20 c) on the opposite side of the second capsule of the damper arm ( 17 k) is guided, preferably in serpentine lines which are transverse to the tilting plane of the damper arm ( 17 k), and tightens a loop ( 42 ) at the free end, which is fastened in a projection ( 17 ka) of the other end of the damper arm ( 17 k). 11. Damping mechanism unit according to claim 2, characterized in that in a recess on the button ( 4 a) pointing side of the lifting member ( 11 a) a wheel ( 45 ) is rotatably mounted, the axis (H) parallel to the axis (B) of the lifting member ( 11 a), and on the button ( 4 a) to the lifting member ( 11 a) pointing projection ( 43 a) is attached, at the free end of which a strip ( 44 ) of soft material is attached, which runs in this way that comes under the side of the wheel ( 45 ) pointing to the button ( 4 a). 12. Damping mechanism unit according to claim 3, characterized in that the damper element or part of the damper element ( 22 a ', 22 ', 51 ) made of heavy material, preferably metal, or heavy material ( 52 ) on part of the damper element ( 22 a) is applied. 13. Damping mechanism unit according to one of claims 1, 2 or 3, characterized in that many on the mechanical beam Damping mechanism units arranged parallel to one another for strings of different pitches.