EP0270966A2 - Electronic organ keyboard - Google Patents

Abstract

A manual for an electronic organ wherein the depression of keys takes place against resistance similar to that encountered on depression of piano keys. Thus, each key of the manual at first offers a pronounced resistance and thereupon a greatly reduced resistance to depression. Pusher is pivotably mounted on the key and cooperates with a convex cam face on a pivotable reaction lever such that the key must abruptly pivot the lever from one toward another end position during the initial stage of depression but the pusher is free to slide relative to the cam face in response to further depression of the key. The lever has a first arm which pivots the pusher relative to the cam face in response to pivoting of the lever from the one end position to thus reduce the force which the pusher can transmit to the lever, and the lever further comprises a second arm which carries a weight tending to pivot the lever back to its one end position. The lever can be arrested in a position out of reach of the pusher so that the key can be depressed solely against the opposition of a spring as in a standard manual. The cam face slopes away from the path of movement of the tip of the pusher in response to depression of the key to thereby further ensure that the resistance which the key encounters to depression decreases as the key continues to move away from its non-depressed position.

Description

The invention relates to a keyboard for an electronic organ with piano effect, in which each key is pivotally mounted against spring force about a first horizontal axis of rotation and via a plunger attached to the key when the key is pressed against a control cam on a second horizontal axis of rotation swivels multi-arm reaction lever and swivels this while moving the control curve first against a large and then against a small reaction force from a first end position to a second end position.

In order to simulate the touch behavior of a piano keyboard for the player of such an organ when choosing the piano effect, the reaction lever is in a known keyboard of the generic type (DE-AS 24 26 016) by eline plunger rigidly attached to the key against the force of one with her a leg on the first arm of the reaction lever torsion spring pivoted as soon as the plunger comes into contact with the control curve attached to this arm. From the beginning, only one component of the force with which the button is actuated is converted into the pivoting movement of the reaction lever. In addition, unlike conventional piano mechanics, the reaction lever has only a small mass. To have sufficiently high reaction forces through the reaction lever on the button To allow their actuation to be effective, a high return spring force and correspondingly complex return spring are required. However, the reaction force is independent of the acceleration (change in speed) with which the key is struck.

The invention has for its object to provide a keyboard of the generic type, in which the dynamic behavior of each key is simulated when actuated with simple means, but higher accuracy than a classic piano mechanics.

According to the invention, this object is achieved in that the plunger is articulated on the key and in the first end position of the key lies with its one long side in the path of a first arm of the reaction lever and with its free end is perpendicular to one end of the control curve which extends from its plunger system point over a sloping arc in the actuating direction of the plunger, that a second arm of the reaction lever has an additional mass which exerts an inertial torque on the reaction lever in the direction of the first end position, and that the distance of the Ram contact point from the axis of rotation of the reaction lever is significantly smaller than the distance of the center of gravity of the additional mass from this axis of rotation.

With this design, the impact force exerted on the plunger when the key is pressed is initially almost completely transferred to the first arm of the reaction lever, which has the control curve, as is the case with classic piano mechanics (in accordance with DIN 8992 from January 1971). Due to the small ratio of the distances between the ram contact point and the additional center of mass from the axis of rotation of the reaction lever and due to the plunger force acting fully on the reaction lever arm carrying the control cam, there is a relatively high acceleration of the additional mass from the start and thus a correspondingly high reaction force (corresponding to the product of mass and acceleration), whereby instead of the large number of components, the classic Mechanics essentially only get along with the plunger and the reaction lever having the control cam and the additional mass, but the additional mass can also be relatively small. Shortly after pressing the button, the second lever arm causes the tappet to pivot, so that its force is no longer directed perpendicularly to the control cam (ie to a tangent in the tappet contact point of the control cam), but rather the tappet begins to move along the control cam with the consequence that only one component of the tappet force is effective on the control cam or the reaction lever arm carrying the control cam. At the same time, the distance of the plunger from the axis of rotation of the reaction lever increases, and the reaction force of the reaction lever suddenly decreases accordingly. Then the key is very easy to press - in accordance with classical piano mechanics. The plunger can therefore be designed simply as a straight rod, without an additional lever arm as in the conventional jack of classical piano mechanics and without its release man with which the lever arm of the jack comes into contact, since the second reaction lever arm takes over the release function.

It can then be ensured that an adjusting weight piece is displaceably mounted along a reaction lever arm, the torque of which counteracts the inertia torque of the additional mass about the axis of rotation of the reaction lever. By moving the adjustment weight in the direction of the axis of rotation of the reaction lever, the force exerted on the plunger by the additional mass increases and thus the initial key resistance, which the player clearly feels. The greater the initial resistance of the button, the more clearly the player feels the trigger point at which the plunger begins to slide on the control curve from its initial position. By adjusting the adjustment weight piece, an optimal adaptation of the actuation process of the plunger to that of the jack of classical piano mechanics is possible.

It is also expedient if the second reaction lever arm has a cushion for resting on the free end of the plunger near the second end position. In this embodiment, the plunger simultaneously takes over the function of the catcher of the classical piano mechanics and the first reaction lever arm the function of the classic counter catcher, without a counter catcher handle being provided on the reaction lever. Furthermore, the reaction lever can be repeated very quickly from the position in which it rests with its cushion on the free end of the plunger, for example in order to play a tremolo.

In order to make the actuation of the key as independent of frictional forces as possible, at least one of the contact surfaces of the control cam and tappet can be slidable.

Instead of this slidable configuration of at least one of the contact surfaces of the cam and tappet, it is also possible to form at least one of the two contact surfaces of the cam and tappet by means of a roller.

Then at least one of the contact surfaces of the cam and tappet can be padded to dampen impact noises.

Due to manufacturing tolerances, a play can occur between the tappet and the cam. In order to compensate for the play, it can therefore be ensured that the pivoting movement of the reaction lever is limited by padded stops determining its end positions, of which the stop determining the first end position is adjustable in the pivoting direction of the reaction lever. By correspondingly adjusting the adjustable stop, a play between the tappet and the control cam can be compensated for, shock and noise damping being achieved simultaneously by the padding of the stops.

Another adjustment possibility can be achieved in that the second reaction lever arm is divided into two sections connected by a lockable joint. By releasing the articulated lock and relative rotation of the two reaction lever arm sections, a play between the tappet and the control cam can also be compensated for.

A particularly simple embodiment of the play compensation device can consist in that the joint is a film joint and each of the two sections of the second reaction lever arm has a projection which extends transversely to the longitudinal direction of the second reaction lever arm and that the angle of rotation distance of the two projections is adjustable by an adjusting screw connecting the projections .

Furthermore, it can be ensured that the reaction lever in the second end position outside the operating range of the plunger by a shut-off device can be locked. The keyboard can then be adjusted to the behavior of an organ or piano keyboard by operating the shut-off device accordingly.

• Fig. 1 bis 4 eine Seitenansicht eines Teils einer er­findungsgemäßen Tastatur in verschiedenen Be­triebsstellungen, teilweise im Schnitt,
• Fig. 5 bis 7 eine Seitenansicht eines Teils eines zwei­ten Ausführungsbeispiels einer erfindungsgemäßen Tastatur, teilweise im Schnitt,
• Fig. 8 und 9 eine Abwandlung des Reaktionshebels des Ausführungsbeispiels nach den Fig. 5 bis 7 und
• Fig. 10 eine weitere Abwandlung des Reaktionshebels des Ausführungsbeispiels nach den Fig. 5 bis 7.

The invention and its developments are described below with reference to the drawing of preferred embodiments. Show it:

• 1 to 4 is a side view of part of a keyboard according to the invention in different operating positions, partly in section,
• 5 to 7 is a side view of part of a second embodiment of a keyboard according to the invention, partly in section,
• 8 and 9 a modification of the reaction lever of the embodiment of FIGS. 5 to 7 and
• 10 shows a further modification of the reaction lever of the exemplary embodiment according to FIGS. 5 to 7.

1 to 4, each key 1 is pivotally mounted about an axis of rotation 2 against the force of a return spring 3. The key 1 actuates an electrical switching element 4, which has a contact spring 5, which is brought into contact with a fixed contact 7 in the rest position by a contact plunger 6 and with a fixed contact 8 in the working position.

On the lever arm of the button 1 opposite the actuating lever arm of the button 1 with respect to the axis of rotation 2, a plunger 10 is pivoted about a horizontal axis of rotation 11. The plunger 10 is by the force of a spring 12, here a leaf spring, on the plunger 10 is fastened and rests loosely on the button 1, pressed against a first arm 13 of a reaction lever 14 which is pivotally mounted about a horizontal axis 15. The reaction lever 14 has a second arm 16, at the end of which an additional mass 17 is attached. Between the arms 13 and 16, the reaction lever 14 is provided with a control cam 18 in the form of a circular arc, at one end of which the free end of the plunger 10 bears vertically in the one end position (the rest position) of the reaction lever 14 shown in FIG. 1, wherein the longitudinal axis of the straight, rod-shaped tappet 10 extends perpendicular to a tangent to the control cam 18 in the tappet contact point. The axis of rotation 15 and the control curve 18 lie approximately on the same circle around the center of curvature 19 of the control curve 18. The control curve 18 is convexly curved and its ends adjoin pads 20 and 21 whose tappet contact surfaces are at an angle to the control curve 18 and each extend approximately in the longitudinal direction of the arms 13 and 16 of the reaction lever 14, the plunger 10 in the end position of the button 1 shown in FIG. 1 lying flat against the cushion 20 with a side face.

The end positions of the reaction lever 14 are determined by stops 22 and 23 for the arm 16 or by stops 24 and 25 for a stop plate 26 attached to the arm 13 and extending it. Here, the contact surfaces of the stops 22 to 25 can be padded to dampen the stop noises. The stops 22 to 25 can be designed as horizontally continuous strips which are common to the reaction lever arms 14 of all keys 1.

To a possibly due to manufacturing tolerances between the free end of the plunger 10 and the To compensate for control curve 18 in the end position shown in FIG. 1, the stop 22 or 24 is adjustable in the direction of the double arrow 27 or 28 about the axis of rotation 15 of the reaction lever 14, so that the arm 16 with the additional mass 17 in the shown rest position practically not on the stop 22 or the stop 24, but on the cam 18 on the free end of the plunger 10, whereby it is ensured that the overall center of mass of the reaction lever arm 16 is approximately at the same level with the axis of rotation 15, so that the total weight of the reaction lever arm 16 always exerts a torque about the axis of rotation 15 counter to the direction of actuation of the reaction lever 14 caused by the key 1.

In order to be able to adjust the load on the plunger 10 by the reaction lever 14 in the end position shown in FIG. 1, there is an adjustment weight piece 29 on a third reaction lever arm 30, which is approximately in the same direction as the arm 16, but on the arm 16 opposite side of the axis of rotation 15 extends, axially displaceably mounted in the direction of the double arrow 31. The lever arm 30 can be a threaded rod and the weight 29 can be a nut.

By means of a shutdown device 32, which is arranged below the reaction lever arm 16 and has a lever 33 for each reaction lever 14 or button 1, which can be pivoted by rotating a shaft 34 common to all reaction levers 14, by rotating the shaft 34 and swinging up the lever 33 iln the position shown in Fig. 4, all reaction lever 14 are locked in the upper end position at the stop 23 or 25, so that there is a distance between the cushion 21 and the free end of the plunger 10. In this position, the reaction lever 14 can all buttons 1 can be freely operated like an organ without the reaction lever 14 also being pivoted. Instead of providing a separate lever 33 for each reaction lever 14, it is sufficient, however, to provide only one lever 33 at the lateral ends of the keyboard and to connect the two levers 33 by means of a rod common to all reaction levers 14, which when the two levers 33 are pivoted upwards Rotation of the shaft 34 presses the reaction lever 14 against the stop 23 or 25.

The pivoting of the parking device 32 can be effected by means of an electromagnetic rotary drive, not shown, which can be triggered by pulling a register while actuating an associated switch.

When the parking device 32 assumes the position shown in FIGS. 1 to 3 and the key 1 is actuated against the force of the spring 3, the plunger 10 in the position shown in FIG. 1 initially transmits the pivoting movement of the key 1 fully to the reaction lever 14, wherein the reaction force exerted on the button 1 by the reaction lever 14 is directly proportional to the acceleration with which the button 1 is actuated. The reaction force is relatively high because of the relatively large distance of the additional mass 17 from the axis of rotation 15 and the relatively small distance of the plunger 10 from the axis of rotation 15, so that the additional mass 17 can be chosen to be correspondingly small. Simultaneously with the upward pivoting of the reaction lever arm 16, the plunger 10 is pivoted clockwise by the elastic cushion 20 of the reaction lever arm 13 until it has reached the position shown in FIG. 2, the so-called release position. In this position oblique to the control cam 18, the tappet 10 begins to slide on the control cam. The game l feel this because button 1 is easier to move from this position.

Key 1 now continues to move to its lower (not shown) stop. During this time, the plunger 10 slides along the control cam 18 without any appreciable frictional connection. At the same time, the reaction lever arm 16 leaves the plunger until it strikes the stop 23 or the other reaction lever arm 13 with its stop plate 26 at the stop 25. From this second end position, the reaction lever 14 is turned back by the cushion of the stop 23 or 25 and the weight of the lever arm 16 in connection with the weight of the additional mass 17, in order then to rest on the plunger 10 with its elastic cushion 21. The reaction lever 14 has thus assumed the position shown in FIG. 3 for rapid repetition.

In this embodiment, the plunger 10 is guided through the control cam 18 to the cushion 21 or reaction lever arm 16 solely by appropriate shaping of the reaction lever 14 and the control cam 18 without the conventional trigger man acting on an additional lever of the plunger. The reaction lever arm 16 therefore simultaneously takes over the task of the conventional counter-catcher with its cushion 21 and the plunger 10 at the same time the task of the conventional catcher.

The closer the adjustment weight piece 29 is moved to the axis of rotation 15, the heavier the part of the reaction lever 14 lying to the right of the axis of rotation 15. This in turn manifests itself in a greater load on the plunger 10 in the position shown in FIG Key resistance that the player clearly feels. The point at which the tappet 10 on the control cam 18 to the right begins to slide, the more clearly the player perceives the greater the resistance in button 1. With this adjustment of the adjustment weight piece 29, an optimal adjustment of the triggering process to that of the classical piano mechanics is possible.

"Keyboard" players often prefer an inclined position of the instrument, often so that the grip area of the keys is higher than their axis of rotation 2. With this version of the keyboard, this is easily possible, even with a 40 ° inclination, the function does not change significantly.

The embodiment according to FIGS. 5 to 7 differs from that according to FIGS. 1 to 4 essentially only in that the reaction lever 114 and the parts interacting with it do not lie above the button 1, but below the grip area of the one end button 1 pivotable about the horizontal axis 2 are arranged. Furthermore, the control curve 118, in contrast to the control curve 18, is provided on the side opposite the reaction lever arm 16 with the additional mass 117 with respect to the axis of rotation 15 on the reaction lever arm 113 and not on the reaction lever arm 116.

The operation of the keyboard according to FIGS. 5 to 7 is essentially the same. If the key 1 is moved down by approximately 70% of its possible path, the plunger 10 and the reaction lever 114 are rotated into the position shown in FIG. 6. By rotating the reaction lever 114, the cushion 20 has pivoted the plunger 10 into the position shown. This is the trigger position. From then on, the plunger 10 slides downward along the control cam 118, and the drive for further rotation of the reaction lever 114 is interrupted.

The key 1 is then pressed without any appreciable resistance against its lower (not shown) stop. At the same time, the reaction lever arm 116 with the additional mass 117 swings due to its kinetic energy up to the upper elastic stop 23. Here it is stopped and then falls back onto its lower elastic stop 27 into the position shown in FIG. 7. When the button 1 is released, it goes back to its upper stop (not shown) and the plunger 10 returns to its starting position according to FIG. 5.

In this exemplary embodiment, too, an adjustment weight piece (not shown) (corresponding to the adjustment weight piece 29 in FIG. 1) is provided in the area of the control curve 118.

Here, too, compensation of the tappet 10 and the control cam 118 by height adjustment in the direction of the double arrow 27 is possible.

To set the reaction lever 114 (in order to disengage it from the plunger 10) up to the upper stop 23, the parking device 32 is again provided.

This embodiment example also allows the keyboard to be tilted, as is often desirable for keyboards.

In the modification of the reaction lever 114 according to FIGS. 8 and 9, the reaction lever arm 116 is divided into two sections 116a and 116b, which are articulated by a film joint 35. Each lever arm section 116a and 116b has a projection 36 and 37 projecting transversely to the longitudinal direction of the lever arm 116, which can be pivoted relative to one another by an adjusting screw 38 which passes through a thread-free bore of the projection 37 and engages in a threaded bore of the projection 36 in order to compensate for a play between the tappet 10 and the control cam 118. If the gap 39 is narrowed according to FIG. 9 with the aid of the adjusting screw, the reaction lever arm 116 is kinked in the region of the film joint 35. The additional mass 117, as shown in FIG. 9, is thus also adjusted upward, so that the additional mass 117 only after a further rotation of the lever arm 113 relative to the position shown in FIG. 8 clockwise on the tappet to compensate for the play between the tappet and the cam 118. The lower stop 22 is not adjustable in this embodiment.

In the modification of the reaction lever 114 according to FIG. 10, the control cam is formed by a roller 118ʹ which is rotatably mounted about an axis 41 between two bearing arms 40. Otherwise, this reaction lever is designed in the same way as the reaction lever 114 according to FIGS. 8 and 9.

Due to the roller 118 alternative, which can alternatively also be provided at the free end of the tappet 10, the sliding friction between the tappet 10 and the control cam is largely avoided. It is therefore possible to do without lubricant between the tappet and the control cam, as would be necessary if at least one of the contact surfaces between the tappet and the control cam is not designed as a roller, but is only padded or made of elastic material such as rubber, silicone or the like To avoid impact noises. Such upholstery fabrics have too high a coefficient of friction, which requires lubrication. However, oiling or lubricating the mechanics of an organ would require a lot of maintenance mean. Many elastic plastics also have the risk of being decomposed by unsuitable lubricants.

The use of a roller, such as roller 118ʹ, as a control cam therefore not only makes lubrication unnecessary, but also enables the free choice of a cushion material covering the roller and / or the end of the tappet.

Modifications of the illustrated exemplary embodiments lying within the scope of the invention can consist in that the very weak leaf spring 12 is replaced by a corresponding spiral spring, e.g. a leg spring or a torsion spring, replaced or the plunger 10 itself is designed to be flexurally elastic. Instead of on its own lever arm, such as lever arm 30, the adjusting weight piece 29 can also be slidably mounted on the reaction lever arm 13 or 113. Instead of the adjusting weight piece 29 and the lever arm 30, it is possible to mount the additional mass 17 on the reaction lever arm 16 in a displaceable manner. The stop plate 26 can be formed in one piece with the reaction lever arm 13 or by the latter itself. Instead of the film joint 35 in the exemplary embodiments according to FIGS. 8 to 10, a joint with joint bolts can be provided. If the hinge pin is designed as a screw bolt, the hinge can be locked by means of a nut fitting on the screw bolt, so that the projections 36 and 37 and the adjusting screw 38 are omitted. Alternatively, the length of the tappet can be made adjustable for the play compensation between the tappet and the control cam, e.g. by dividing the ram into two axially screwable and lockable sections.

Electronic pianos or so-called "keyboards" should also be included here under "electronic organ".

Claims (11)

Keyboard for an electronic organ with piano effect, in which each key is pivoted against spring force about a first horizontal axis of rotation and presses against a control cam on a multi-arm reaction lever which can be pivoted about a second horizontal axis of rotation via a plunger attached to the key and presses it while moving the control cam first against a large and then against a small reaction force from a first end position to a second end position, characterized in that the plunger (10) is articulated on the button (1) and in the first end position of the button (1 ) with its one long side in the path of a first arm (13; 113) of the reaction lever (14; 114) and with its free end perpendicular to one end of the control cam (18; 118; 118ʹ, which extends from its tappet Contact point extends over an arc falling in the actuating direction of the plunger (10) that a second arm (16; 116) of the reaction lever (14; 114) has an additional mass (17; 117) which exerts an inertial torque on the reaction lever (14; 114) in the direction of the first end position, and that the distance of the tappet contact point from the axis of rotation (15) of the reaction lever (14 ; 114) much smaller than the distance of the center of gravity of the additional mass (17; 117) from this axis of rotation (15). 2. Keyboard according to claim 1, characterized in that along a reaction lever arm (3) an adjusting weight piece (29) is slidably mounted, the torque about the axis of rotation (15) of the reaction lever (14, 114) the inertia torque of the additional mass (17; 117) counteracts. 3. Keyboard according to claim 1, characterized in that the second reaction lever arm (16) has a cushion (21) for resting on the free end of the plunger (10) near the second end position. 4. Keyboard according to one of claims 1 to 3, characterized in that at least one of the contact surfaces of the cam (18; 118) and plunger (10) is slidable. 5. Keyboard according to one of claims 1 to 3, characterized in that at least one of the two contact surfaces of the cam (118ʹ) and plunger (10) is formed by a roller. 6. Keyboard according to claim 4 or 5, characterized in that at least one of the two contact surfaces of the cam and plunger is padded. 7. Keyboard according to one of claims 1 to 6, characterized in that the pivoting movement of the reaction lever ((14; 114) by its end positions determining padded stops (22, 23; 24, 25) is limited, of which the first end position stop (22; 24) in the pivoting direction (27; 28) of the reaction lever (14; 114) is adjustable. 8. Keyboard according to one of claims 1 to 6, characterized in that the second reaction lever arm (116) is divided into two sections (116a; 116b) connected by a lockable joint (35). 9. Keyboard according to claim 8, characterized in that the hinge is a film hinge (35) and each of the two sections (116a; 116b) of the second reaction lever arm (116) has a projection extending transversely to the longitudinal direction of the second reaction lever arm (16) ( 36; 37) and that the angle of rotation distance of the two projections (36, 37) is adjustable by means of an adjusting screw (38) connecting the projections. 10. Keyboard according to one of claims 1 to 9, characterized in that the reaction lever (14; 114) in the second end position outside the operating range of the plunger (10) can be locked by a parking device (32). 11. Keyboard according to one of claims 1 to 10, characterized in that the plunger (10) can be reset to the plunger contact point by spring force (12).

Images