RU2813957C1 - Musical instrument keyboard - Google Patents

Abstract

FIELD: musical instruments.

SUBSTANCE: invention relates to musical instruments and can be used in keyboard musical instruments. Result is achieved due to the fact that a keyboard for a musical instrument, comprising a housing made in the form of upper and lower parts, between which keys are mounted by means of hinged rolling levers, wherein the lever is mounted through a through hole in the upper part of the housing, upper, resting on top of housing, end of rolling lever is equipped with roller, on which one end of the string is mounted with the possibility of its tension when pressing the key and loosening when the key is returned to the initial position before pressing, spring stretched between the lever and the back wall of the housing with the possibility of returning the key to the initial position after its pressing.

EFFECT: providing reliability and operational manufacturability due to minimum sufficient number of elements of keyboard devices designed to expand expressive capabilities of musical instruments.

10 cl, 16 dwg

Description

The invention relates to musical instruments and can be used in keyboard musical instruments [G10C 3/12, G10C 3/16, G10C 1/00, G10C 3/00].

The main means of expressiveness in music include mode, harmony, rhythm, tempo, dynamics, timbre, articulation, intonation, etc. An increase in the degrees of freedom of the keyboard devices of musical instruments provides variations in timbre, tone, pitch and volume of sound generated in accordance with variations in the static load when touching the keys.

Known from the prior art is a PIANO TONE CONTROL [JP 2008008971 A, publ.: 01/17/2008], containing a mechanism for striking a string for pressing a key, a variable static load device and an electronic device for adjusting the musical tone, while the variable static load device is made of of a plurality of weight arms and has a long shape, one end portion of each of the weight arms in the longitudinal direction above one key corresponding to each of the weight arms among the plurality of piano keys can be rotated in the vertical direction and contact the top surface of the corresponding key on the side opposite to the playing side , under the influence of its own weight.

A KEYBOARD DEVICE [US 7297854 B2, publ.: November 20, 2007] is known from the prior art, containing a support element, a plurality of keys, each of which has a drive part and is located on the specified support element in such a way that each key can rotate around its base end portion, wherein said keys comprise a plurality of white keys and a plurality of black keys, a plurality of pivot motion supports secured to said support member, and a plurality of mass bodies so provided, which are respectively associated with said pivot motion supports, and each of which has a driven part, and the specified mass bodies are located with the possibility of rotation around the corresponding ones associated with the specified supports of the rotary movement, and contain masses associated with the white keys, which are associated with the specified white keys, respectively, and mass bodies associated with the black keys, which associated with said black keys, respectively, wherein said driving portion of each key drives said driven portion associated with one of said mass bodies in accordance with the rotational movement of said key, whereby said associated mass body rotates about said associated support for the rotational motion, and wherein said driven part of each mass body associated with the white key and said driven part of each mass body associated with the black key are in the same longitudinal position, and at the same time the distance between said driven part of the said mass body , associated with the black key, and the specified rotation support associated with it, is greater than the distance between the specified driven part of the specified mass body associated with the white key and the specified rotation support associated with it.

A KEYBOARD DEVICE is known from the prior art [WO 2017164232 A1, publ.: 09/28/2017], containing a key, a guide that regulates the direction in which the key moves, and the guide is located in three or more places that are not aligned in a straight line, if is viewed along the scale direction of the key, and the guide is slidably in contact with the key on the scale direction side, and a connecting portion connecting the key to the frame on the rear side of the key from the guide, wherein the connecting portion includes a rod-shaped flexible member.

Known from the prior art is a KEYBOARD DEVICE FOR MUSICAL INSTRUMENTS [JPH 0442198 A, publ.: 02.12.1992], having a structure capable of moving in a direction independent of the direction of movement, centered on the supporting element of the key by pressing.

The closest in technical essence are the METHOD AND DEVICE FOR PRODUCING MUSICAL INSTRUMENTS CONTROLLED BY A KEYBOARD, CHANGING TONE, CONTROLLED BY VARIATIONS OF HEIGHT, ETC. [GB 1573233 A, publ.: 08/20/1980], having flat longitudinally elongated keys for manual pressing in order to reproduce sounds, means for centering and positioning the keys, including, inter alia, a lever connected to each mentioned key, a spring, connected to the lever using the first fastener and to the upper part of the housing using the second fastener.

The main technical problem of the analogues and the prototype is the complexity of the system for connecting the device components, which does not ensure operability, reliability and ergonomic use.

The main objective of the invention is to eliminate the disadvantages of analogues and the prototype.

The technical result consists in ensuring reliability and manufacturability due to a minimum sufficient number of elements of keyboard devices designed to expand the expressive capabilities of musical instruments.

The specified technical result is achieved due to the fact that a keyboard for a musical instrument contains a housing made in the form of upper and lower parts, between which keys are mounted using articulated rolling arms, while the lever is mounted through a through hole in the upper part of the housing, the upper, resting on top of the body, the end of the swing lever, is equipped with a roller on which a string is mounted at one end with the possibility of tensioning it when pressing a key and loosening it when returning the key to its original position before pressing, a spring stretched between the lever and the rear wall of the body with the possibility of returning the key to initial position after you stop pressing it.

In particular, the through hole in the upper part of the housing, through which the lever is mounted, is designed to limit the angular movement of the lever.

A keyboard for a musical instrument, comprising a housing in which keys protruding outwards with their proximal ends are mounted, made with the possibility of reciprocating movement in the longitudinal and transverse directions, a pipe with a movable slide, configured to regulate the air column and a valve that allows opening and closing pipes, a lever mounted through a through hole in the upper part of the body and pivotally connected to each of the keys and spring-loaded with the body by means of two springs directed in opposite directions from the lever to the body, the upper end of the lever is connected to the rocker to transmit reciprocating motion to it longitudinal direction, the lower end of the lever is hinged on the key, the distal end of the key is mounted through the bar to the valve to transmit to it reciprocating movements in the vertical and transverse directions.

In particular, the upper part of the body is U-shaped.

In particular, the connection between the key and the bar is made using an eyelet in the bar and a pin with a head.

A keyboard for a musical instrument containing a housing made in the form of upper and lower parts, between which, using rolling levers, the rolling axis of which is made in the middle part of the lever, keys are mounted with the ability to move them in the longitudinal direction due to the angular movement of the lever, while the lever mounted through a through hole in the upper part of the body, a roller is mounted on the axis of rotation of the lever, on which a string rests, mounted with its end to the string tension bar, the upper end of the lever is connected by a spring to the spring tension bar with the ability to change the rigidity of the key, which is mounted pivotally to the lower end lever, the lever is equipped with a tension roller that interacts with the string in its section from the roller on which the string rests and the string tension bar, while the hinged connection of the key and the lever is made with the possibility of vertical reciprocating movement of the key along the lever to interact with the proximal ends with potentiometers, mounted in the lower part of the housing due to the hinge connection made in the lower part of the lever.

In particular, the string tension bars and springs are equipped with screws mounted through the body wall, the caps of which are located outside.

In particular, to interact the key with the potentiometer, a protrusion is made in its lower part.

A keyboard for a musical instrument, containing a housing made in the form of upper and lower parts, between which keys rest on springs mounted in the lower part of the housing, at the distal ends of which counterweights are mounted, ensuring a shift of the center of gravity of the keys to the distal end, while the keys are made with the possibility of displacement relative to the axis of the spring when acting on the proximal end of the key and back, after the end of the impact on the key due to the counterweight, while in the upper part of the body for each key there are V-shaped recesses that allow the keys to slide in them when they are displaced, in the lower part On the proximal end of the keys, sensors are mounted that interact when displaced with their corresponding parts, mounted on the lower part of the housing under the sensors and causing the appearance of an electrical signal that is converted into an audio signal.

In particular, the spring is connected to the key and to the lower part of the housing through supports.

Brief description of the drawings.

In fig. Figure 1 shows a top view of the proposed device.

In fig. Figure 2 shows a cross-sectional view of the proposed device AA.

In fig. Figure 3 shows a cross-sectional view of the proposed device.

In fig. Figure 4 shows a cross-sectional view of the inventive device AA, where the black key 4 is pressed and moved forward relative to the body.

In fig. 5 shows a top view of the inventive device, where the black key 4 is pressed and moved forward relative to the body.

In fig. Figure 6 shows a cross-sectional view of the inventive device AA, where the black key 4 is pressed and moved back relative to the body.

In fig. 7 shows a top view of the inventive device, where the black key 4 is pressed and moved back relative to the body.

In fig. 8 shows a top view of the inventive device, which shows white keys 3 and black keys 4 when performing reciprocating movements.

In fig. 9 shows on the right a view of the inventive device built into a wind musical instrument.

In fig. 10 shows on the right a view of the inventive device built into a wind musical instrument with an extended key.

In fig. 11 shows on the right a view of the inventive device built into a wind musical instrument with the key pushed in all the way.

In fig. 12 shows a right view of another embodiment of the inventive device with potentiometers 38.

In fig. 13 shows a top view of another embodiment of the inventive device of FIG. 12 with potentiometers 38 in a horizontal version.

In fig. 14 shows a right view of another embodiment of the inventive device with sensors 55.

In fig. 15 shows a top view of an embodiment of the inventive device of FIG. 14.

In fig. Figure 16 shows a top view of the inventive devices (Fig. 12-Fig. 15), where white keys 3 and black keys 4 are presented when performing reciprocating movements.

The figures indicate: 1 - upper part of the body, 2 - lower part of the body, 3 - white keys, 4 - black keys, 5 - string, 6 - roller, 7 - fastenings, 8 - pin, 9 - axis, 10 - supports, 11 - connections, 12 - swing arm, 13 - through hole, 14 - spring, 15 - first fastener, 16 - second fastener, 17 - under-key protrusion, 18 - key, 19 - valve tube, 20 - valve, 21 - rocker, 22 - bell, 23 - whistle, 24 - connection, 25 - additional spring, 26 - third fastener, 27 - fourth fastener, 28 - bar, 29 - eye, 30 - pin with head, 31 - fastening, 32 - string tension bar , 33 - spring, 34 - spring tension bar, 35 - tension roller, 36 - swivel joint, 37 - protrusion, 38 - potentiometers, 39 - first screw, 40 - second screw, 41 - washers, 42 - recess, 43 - fixing roller, 44 - cutout, 45 - eye, 46 - support, 47 - L-shaped lever, 48 - fastening, 49 - spring, 50 - counterweight, 51 - supports, 52 - V-shaped notch, 53 - covering, 54 - grooves, 55 - sensors, 56 - mating parts.

Implementation of the invention.

In the present invention, operational manufacturability refers to the manufacturability of a structure when preparing it for its intended use, maintenance and repair of the structure.

The keyboard of the present invention is intended for use in musical instruments. The body of the musical instrument contains at least the upper part of the body 1, the lower part of the body 2, white keys 3, black keys 4, strings 5 (Fig. 1-Fig. 8).

Further in the text of the description, the term “key” is used; the key can be made either white 3 or black 4.

The upper part of the housing 1 partially covers the white 3 and black 4 keys from their distal end.

Moreover, the upper part of the housing 1 and the lower part of the housing 2 are located in parallel, relative to the white keys 3 and the black keys 4, and can be made in a U-shaped, L-shaped or other shape.

Moreover, the upper part of the housing 1 can be made as a partition between the keyboard and the main part of the housing (not shown in the figures) of the musical instrument.

Between the upper part of the housing 1 and the lower part of the housing 2, keys are mounted using articulated swing arms 12 (Fig. 1-Fig. 8) to ensure free reciprocating movements when the key is pressed down.

In this case, the rolling arm 12 is mounted through a through hole 13 in the upper part of the housing 1.

Moreover, the lever 12 can be made of composite materials, non-magnetic metal, etc.

The through hole 13 in the upper part of the housing, through which the swing arm 12 is mounted, is designed to limit the angular movement of the arm.

The upper end of the swing lever 12, resting on top of the body, is equipped with a roller 6, on which a string 5 is mounted at one end with the possibility of tensioning it when the key is pressed and loosening it when the key is returned to its original position before pressing.

Roller 6 has a protruding part made in the form of a pin 8, one end of which is rigidly fixed to roller 6, and fastener 7 is screwed onto the second, clamping the string to roller 6 (see Fig. 2-Fig. 4, Fig. 6) .

Thus, the string 5 for each of the keys is connected in the body by methods known from the prior art at one end (not shown in the figures), and at the other end it is fixed on the roller 6 through fastening 7.

Moreover, pin 8 has a thread.

Moreover, fastening 7 can be made in the form of a threaded bushing, nut, etc.

Moreover, roller 6 is made of a cylindrical shape, thereby ensuring smooth tension of the string during operation of a musical instrument, for example, in the form of a bearing (see Fig. 2-Fig. 4, Fig. 6).

Roller 6 has an axis 9 (Fig. 3), the ends of which protrude beyond the boundaries of said roller 6 and are connected to pairwise supports 10, the other ends of which are connected to the upper part of the housing 1.

Moreover, the roller 6 and the axis 9 can be interconnected by a rigid connection, then the ends of the axis 9 must be fastened by a connection of free rotation with the supports 10, for example, using a threaded or through hole at the ends of the axis 9, etc. (not shown in the figures).

Moreover, the roller 6 and the axis 9 can be interconnected by a connection of free rotation, then the ends of the axis 9 must be rigidly fastened to the supports 10, for example, using terminal connections, threaded ones, etc. (not shown in the figures).

Moreover, the supports 10 are connected to the upper part of the housing 1 by rigid connections 11 to prevent the movement of the roller 6.

Moreover, the supports 10 can be made rigid (for example, from a non-magnetic metal, etc.) and immovable relative to the movement of the roller 6. It is worth considering that the greater the formed angle of the pairs of supports 10 (Fig. 2), the greater their holding capacity.

The swing lever 12 is designed to influence the tension of the string through the roller 6 to adjust the expressive color of the sound (in particular, timbre, tone and pitch of the note, etc.).

Spring 14 (Fig. 2, Fig. 4, Fig. 6) is tensioned between the swing arm 12 and the rear wall of the housing with the ability to return the key to its original position after stopping pressing it.

The spring 14 is connected to the swing arm 12 using the first fastener 15 and to the upper part of the housing 1 using the second fastener 16 (see Fig. 2, Fig. 4, Fig. 6).

Moreover, the first fastener 15 and the second fastener 16 can be made in the form of a hook through a loop (eye) and hooks.

Moreover, for better holding capacity of the spring 14, the second fastener 16 can be made in a Y-shape.

Moreover, the sub-key protrusion 17 (Fig. 2, Fig. 4, Fig. 6) of the white keys 3 is designed so as not to limit the maximum extension of the black keys 4 during reciprocating movements.

Moreover, in Fig. 8 shows the possibility of using the proposed method for both black keys 3 and white keys 2.

The other end of these keys acts on the activation mechanism of string 5, for example, a hammer, plectrum, pick or other (not shown in the figures).

The musical instrument may also be provided with a damper, soundboard, etc., as well as pins for connecting the other end of the string 5 to the soundboard.

Another embodiment of the proposed device is shown in Fig. 9-fig. eleven.

In fig. 9-fig. Figure 11 shows the inventive device, made for a wind musical instrument, having at least a body (in Fig. 9-Fig. 11 is shown as the upper part of the body 1), in which keys 18 protruding outward with their proximal ends are mounted, made with the ability to return - translational movement in the longitudinal and transverse directions, a pipe (in Fig. 9-Fig. 11 is shown as a valve tube 19) with a movable slide 21, valve 20, mouthpiece (not shown in the figures), bell 22, slot.

Moreover, the gap forms whistle 23.

The slide 21 is made with the ability to regulate the air column.

Moreover, the valve 20 is made hinged.

Valve 20 provides the ability to open and close valve tube 19.

In the upper part of the housing 1 there is a through hole 13, in which a lever 12 is built longitudinally to ensure free reciprocating movements when pressing a key in the longitudinal or transverse directions.

Lever 12 is pivotally connected to each of the keys 18.

The lever 12 is spring-loaded with the housing (in Fig. 9-Fig. 11 shown as the upper part of the housing 1) by means of two springs, spring 12 and an additional spring 25, directed in opposite directions from the lever 12 to the housing.

The spring 14 is connected to the lever 12 using the first fastener 15 and to the upper part of the housing 1 using the second fastener 16.

Between the lever 12 and the upper part of the housing 1, an additional spring 25 is mounted using a third fastener 25 and a fourth fastener 26, located at the same level as the above-mentioned spring 14, to allow the key to return to its original position after stopping pressing it, taking into account the weight of the slide 21.

The upper end of the lever 12 is connected to the rocker 21 to transmit to it a reciprocating movement in the longitudinal direction.

Moreover, the connection (not shown in the figures) of the lever 12 with the slide 21 can be made hinged or any other, providing rotational movements of the lever 12 when the key is pressed and shifted in the transverse direction.

The lower end of the lever 12 is hinged to the key 18 using connection 24 (Fig. 9-Fig. 11).

The distal end of the key 18 is secured through a bar 28 with a valve 20 to transmit to it reciprocating movements in the vertical and transverse directions.

The connection between the key 18 and the bar 28 is made using an eye 29 in the bar 28 and a pin with a head 30 mounted on the said key 18 to ensure free reciprocating movements of the lever 12 when the key is pressed in the longitudinal and transverse directions.

Moreover, the fastening 31 of the strip 28 to the valve 20 can be hinged or rigid.

Other embodiments of the proposed device are presented in Fig. 12 and fig. 13.

In fig. 12 shows the inventive device containing a housing made in the form of upper 1 and lower 2 parts of the housing.

Between the upper 1 and lower 2 parts of the housing, with the help of rolling levers 12, the rolling axis of which is made in the middle part of the lever 12, keys are mounted with the ability to move them in the longitudinal direction due to the angular movement of the lever 12.

In this case, the rolling arm 12 is mounted through a through hole 13 in the upper part of the housing 1.

A roller 6 is mounted on the axis of rotation of the rolling lever 12, on which a string 5 rests, mounted with its end to the string tension bar 32.

The upper end of the swing arm 12 is connected by a spring 33, the other end of which is fixed to the spring tension bar 34 with the ability to change the rigidity of the key.

The rolling lever 12 is equipped with a tension roller 35 that interacts with the string 5 in its section from the roller 6, on which the string 5 and the string tension bar 34 rest.

In this case, the hinge connection 36 of the key and the swing arm 12 is made with the possibility of reciprocating movement of the key along the swing arm 12 to interact with the proximal ends with potentiometers 38 mounted in the lower part of the housing 2, due to a vertically oriented elongated eye made in the lower part of the lever 12 on which the hinge axis rests (see Fig. 12).

Moreover, for the interaction of the key with the potentiometer, a protrusion 37 is made in its lower part.

Moreover, the protrusion 37 can be made along the key at any distance from its edge.

In the embodiment (Fig. 12, Fig. 13), the tension bars of the string 32 and the spring 34 are equipped with screws (the first screw 39 and the second screw 40) mounted through the wall of the housing, the caps of which are located outside.

The first 39 and second 40 screws have washers 41 for securely fixing the mentioned screws in the housing.

Moreover, the first screw 39 is connected to one of the ends of the string tension bar 32.

The second end of the string tension bar 32 has a recess 42 for the roller 43 fixing the string 5, as well as a cutout 44 for supplying the string 5 (Fig. 12, Fig. 13).

Moreover, the recess 42 and the cutout 44 form an L-shaped groove in the second strip 35.

Moreover, the first screw 39, due to the head, is made with the ability to adjust the tension of the string 5.

Moreover, in FIG. 12 and fig. 13 shows that the second screw 40 is connected to one end of the spring tension bar 34, the second end of which has an eye 45 and is connected to the spring 33.

It is worth noting that the second screw 40, due to the head, is made with the ability to adjust the tension of the spring 34 and, accordingly, change the position of the swing arm 12.

Moreover, the tension roller 35 is mounted on a support 46, rigidly mounted on the lever 12 with the ability to move around its axis to distribute the force and smoothness of the tension of the string 5 between the fixing roller 43 and the roller 6 mounted on the rolling lever 12.

The other end of these keys acts on the mechanism for activating string 5, for example, made in the form of a hammer, plectrum, pick, etc. (not shown in the figures).

The musical instrument may also be provided with at least studs to connect the other end of the string 5 to the soundboard.

Moreover, each string 5 is equipped with pickups (not shown in the figures) to convert the mechanical vibrations of the strings 5 into electric current.

Moreover, the pickups can be made electromagnetic, piezoelectric or optical.

Moreover, the potentiometers 38 and pickups are connected to a control device, for example, a microcontroller (not shown in the figures), which will process data from the potentiometers and pickups via a wired or wireless communication channel.

Moreover, instead of potentiometers 38, sensors or other sensitive elements with similar characteristics can be used.

Moreover, the microcontroller is configured to read data from the potentiometer 38 and the pickup and convert them into sound signals.

Moreover, the microcontroller is made with the ability to program various sound effects (sound volume, expressiveness and dynamics, timbre, filtering frequency, or other effects, depending on the specific design of the musical instrument), which will be activated at different key positions.

Moreover, the microcontroller uses the received data to generate an audio signal, which can be amplified and output through a sound source unit, for example, a speaker (not shown in the figures), creating a sound wave that the listener will hear.

An embodiment of the proposed device (Fig. 12) in a horizontal design and having three potentiometers 38 is shown in Fig. 13.

Moreover, the implementation of the inventive device is not limited to the use of one (Fig. 12) or three potentiometers 38 (Fig. 13) for each mentioned key, which provides various sound effects (sound volume, expressiveness and dynamics, timbre, filtering frequency, or other effects, in depending on the specific design of the musical instrument).

In fig. 13, the rolling lever 47 is made L-shaped in the form of three intersecting bars at one point, forming a right angle between each other.

The first bar of the rolling lever 47 is connected to the said key (in the example of Fig. 13 - white key 3), the connection shown in Fig. 12.

The second bar of the rolling lever 47 is connected to the spring 33 through the mount 48.

A roller 6 is mounted at one end of the third bar of the rolling lever 47, and a tension roller 35 is mounted at the other.

Thus, this design (Fig. 13) is created with the possibility of horizontal control of the first 39 and second 40 screws (Fig. 12), which can be located at different levels for each of the white 3 and black 4 keys.

Moreover, the mentioned screws, washers, strips, springs, rollers, hinge joints, swing arms and protrusions can be made of non-magnetic metals and other composite materials.

Another embodiment of the proposed device is shown in Fig. 14.

The inventive device contains a housing made in the form of upper 1 and lower 2 parts.

Between the upper 1 and lower 2 parts of the housing, the keys rest on springs 49 mounted in the lower part of the housing 2.

Counterweights 50 are mounted at the distal ends of each key to ensure that the center of gravity of the keys is shifted toward the distal end.

In this case, the keys are made with the possibility of displacement relative to the axis of the spring 49 when acting on the proximal end of the key and vice versa, after the end of the impact on the key due to the counterweight 50.

Moreover, the counterweights 50 can be made of various shapes from composite metals, wood, non-magnetic metals, etc., and also connected to the said key with a rigid detachable or permanent connection that prevents its detachment, for example, an adhesive connection, a threaded connection, etc. .

Moreover, the springs 49 can be mounted on supports 51 to ensure uniform pressure on the key during reciprocating movements.

Moreover, the springs 49 are a holder and stabilizer of the keys, and can be replaced with any other element that has similar characteristics.

Moreover, the supports 51 can be made of various shapes from plastic, composite metals, wood, etc., and are also connected to the said key and the lower part of the housing 2 with a rigid connection, which prevents their detachment during the movement of the said key, for example, with a permanent adhesive connection , detachable threaded connection, etc.

Moreover, the supports 51 can be configured to adjust the tension of the spring 49.

In this case, in the upper part of the case, V-shaped recesses 52 are provided for each key, ensuring that the keys slide into them when they are displaced.

Moreover, each V-shaped recess 52 is equipped with a coating 53, which ensures smoothness and soundlessness during the reciprocating movements of the specified key (Fig. 14).

Moreover, the covering 53 can be made of felt or any other material that provides noise reduction when the key comes into contact with the upper part of the body 1.

Moreover, the keys can be equipped with grooves 54 for V-shaped recesses 52 in

upper part of the body 1.

Sensors 55 are mounted in the lower part of the keys at the proximal end, which interact when displaced with their corresponding parts 56, mounted on the lower part of the housing 2 under the sensors 55 and causing the appearance of an electrical signal that is converted into sound.

The response parts 56 may be made of metal, carbon, or any other conductive coating in the form of paint, film, etc., which has sufficient conductivity when in contact with the sensors 55.

Moreover, the sensors 55 are designed to register keystrokes and convert this information into a signal transmitted to the converter.

Moreover, sensors 55 can be made as contact sensors (mechanical, capsule, etc.), which register clicks upon physical contact of the sensor with the mating part.

Moreover, the sensors 55 can be made as piezoelectric elements for recording vibration caused by pressing a key.

Moreover, the sensors 55 can be made as optical sensors (infrared optical sensors) for recording the passage of a light beam when a key is pressed.

Moreover, the sensors 55 can be made as capacitive sensors that detect changes in capacitance when a key is touched.

Moreover, the sensors 55 can be designed as magnetic sensors for recording changes in the magnetic field caused by pressing a key.

Moreover, the sensors 55 can be made as ultrasonic sensors for measuring the distance between the keys and the response part, determining when the key is pressed.

The implementation of sensors 55 is not limited to the above options.

Moreover, the transmission lines (not shown in the figures) of the signal from the sensors 55 to the converter and microcontroller can be made via a wireless communication channel or a wired one located along the above key.

Moreover, the presence of the converter(s) is determined by the characteristics of the sensors 55 used; the converter can be made analog-to-digital.

Moreover, the signal transmission circuit may include a system of filters (not shown in the figures) for sampling the required frequencies and eliminating noise.

Moreover, the signal transmission circuit may include an effects block (not shown in the figures) to improve the purity of the sound, its “transparency”.

Moreover, the signal transmission circuit may include a microcontroller (not shown in the figures) with the ability to program various sound effects (sound volume, expressiveness and dynamics, timbre, filtering frequency, or other effects, depending on the specific design of the musical instrument), which will be activated at different key positions.

Moreover, the signal transmission circuit may include a mixer (not shown in the figures), with the help of which the signal can be further amplified or subjected to other processing.

Moreover, the signal transmission circuit may include a divider (not shown in the figures), due to the introduction of which the signal can be divided into several channels or directed to different blocks of the sound source (not shown in the figures).

Moreover, the microcontroller uses the received data to generate an audio signal, which can be amplified and output through a sound source unit, for example, a speaker (not shown in the figures), creating a sound wave that the listener will hear.

The implementation of the signal transmission circuit from the sensors 55 to the sound source unit(s) is not limited to the above options.

The inventive device (Fig. 1-Fig. 8) works as follows.

It should be noted that pressing the keys of the inventive device (Fig. 1-Fig. 8) is performed by pressing, taking into account the possible movement of the keys in the longitudinal direction forward and backward relative to the upper 1 and lower 2 parts of the housing.

Pressing the key forward (or backward) moves the swing arm 12 within the limits of the angular movement of the arm due to the through hole 13.

Moreover, when longitudinally pressing the key forward (or backward) due to the supports 10 and the specified hinge joint, the lever 12 exerts tension on the string 5.

When the specified key is pressed forward (or backward), the lever 12 activates the roller 6, the string 5 is thus tensioned (released).

As is known, when the activation mechanism strikes string 5, mechanical vibrations of different amplitudes are transmitted to the soundboard and dissipated, which enhances the sound.

Providing different levels of tension on string 5 is accomplished by increasing the number of degrees of freedom of the specified key, which leads to an increase in the number of possible vibration amplitudes of string 5, directly affecting the expressive capabilities of the musical instrument, in particular on timbre, note pitch, etc.

It should be noted that when pressed forward relative to the upper 1 and lower 2 parts of the housing (Fig. 1-Fig. 8), the spring 14 is stretched, and when pressed back, the spring 14 is compressed, providing a return action to the original position after pressing the specified key.

The tension of the spring 14 and the own tension of the string 5 return the key to its original equilibrium position.

Another variant (Fig. 9) of the proposed device, in particular wind instruments, works as follows.

It should be noted that playing a wind instrument (Fig. 9) is performed in a classical manner, supplying a stream of air.

Moreover, the air flow passes through the valve tube 19 and the valve 20, which is in the open state, then enters the slide 21 and is discharged through the bell 22, emitting sound signals.

Valve 20 is opened by pressing key 18.

The distal end of the key 18 moves upward, exerting pressure on the hinge (not shown) of the valve 20, causing it to open.

When you press the key 18 of the inventive design (Fig. 10) in the longitudinal direction forward, it is possible to move the backstage 21 using the lever 12 fixed between them, while the air column increases and the expressive color of the sound changes (in particular, the pitch of the note).

When the key 18 of the inventive design (Fig. 11) is pressed in the longitudinal direction back, the slide 21 can move in the same direction, while the air column decreases and the expressive color of the sound changes (in particular, the pitch of the note).

By pressing the key 18 of the inventive design in the transverse direction to the left or right, it is possible to adjust the expressive color of the sound.

Thus, the key 18, when moving in the transverse direction to the left or right, simultaneously moves the bar 28, which in turn moves the hinge (not shown in the figures) of the valve 20, which causes a change in the volume of air supplied through the valve 20, the level of which directly affects the volume, timbre and so on.

Thus, the expressive color of the sound is varied, in particular, note pitch, timbre and volume.

Another option (Fig. 12, Fig. 13, Fig. 16) of the proposed device works as follows.

It should be noted that pressing the keys of the inventive device (Fig. 12, Fig. 13) is performed by pressing, taking into account the possible movement of the keys in the longitudinal direction forward and backward relative to the upper 1 and lower 2 parts of the housing.

Pressing the key forward (or backward) moves the swing arm 12 within the limits of the angular movement of the arm due to the through hole 13.

Moreover, when longitudinally pressing the key forward (or backward) due to the supports 10 and the specified hinge joint, the lever 12 exerts tension on the string 5.

When the specified key is pressed forward (or backward), the lever 12 actuates the roller 6 and the tension roller 35, the string 5 is thus tensioned (released).

At the same time, when the activation mechanism strikes string 5, mechanical vibrations of different amplitudes are transmitted to the soundboard and dissipated, which enhances the sound.

Providing different levels of tension on string 5 is accomplished by increasing the number of degrees of freedom of the specified key, which leads to an increase in the number of possible vibration amplitudes of string 5, directly affecting the expressive capabilities of the musical instrument, in particular on timbre, note pitch, etc.

These vibrations are recorded by pickups.

The pickups convert mechanical vibrations of the strings 5 into electrical current and transmit data to the microcontroller.

In parallel with these actions, potentiometers 38 record the mechanical action of the key (through protrusion 37) and convert it into electrical current, then transmit the data to the microcontroller.

The microcontroller reads the received data from potentiometers 38 and sound pickups, converts them into sound signals and outputs them to the sound source block.

The audio source outputs them as an audio signal.

Moreover, the reciprocating movements of the lever 12 and, accordingly, the specified key are adjusted by tensioning the spring 33 by screwing in and unscrewing the second screw 40 and, accordingly, the tension spring strip 34, for example, when deforming (stretching) the spring 33, which increases the service life of the specified spring.

The tension of string 5 is adjusted by screwing in and unscrewing the first screw 39 and, accordingly, the string tension bar 32, as well as the roller 43 built into it that fixes string 5.

As is known from the prior art, string tension allows you to adjust their vibration amplitude and, accordingly, the output sound.

Another variant (Fig. 14, Fig. 16) of the proposed device works as follows.

Pressing the specified key in the longitudinal and transverse directions leads to compression of the spring 49 (Fig. 14, Fig. 16).

Sensor 55 touches mating part 56.

The sensor 55, depending on its type and the selected response part 56, registers a touch signal (and its duration).

From the sensor, signal information is transmitted to the converter and/or microcontroller via wired or wireless communication channels.

The converted signal from the microcontroller goes to the sound source block(s) for playback.

Moreover, the signal transmission line from the sensor 55 to the sound source unit(s) can be carried out through several additional signal conversion devices described above.

The return of the key to its original position is carried out using a counterweight 50, the return properties of the spring 49, provided by this design of the V-shaped recesses 52 in the upper part of the housing 1.

The sound of the keys beating on the top of the housing 1 does not allow coating 53.

Thus, the author of the application for the invention created working models of the claimed devices, which, in comparison with the prototype and analogues, are made with a minimum sufficient number of elements for each design without compromising their reliability and manufacturability, which is compensated by the above-described elements, their interconnections and the specified properties .

Claims (10)

1. A keyboard for a musical instrument, comprising a housing made in the form of upper and lower parts, between which keys are mounted using articulated rolling arms, the lever being mounted through a through hole in the upper part of the housing, the upper end of the rolling lever resting on top of the housing equipped with a roller on which a string is mounted at one end with the possibility of tensioning it when the key is pressed and loosening it when the key is returned to its original position before pressing, a spring stretched between the lever and the rear wall of the case with the possibility of returning the key to its original position after stopping pressing it. 2. The keyboard for a musical instrument according to claim 1, characterized in that the through hole in the upper part of the body, through which the lever is mounted, is designed to limit the angular movement of the lever. 3. A keyboard for a musical instrument, containing a housing in which keys protruding outwards with their proximal ends are mounted, made with the possibility of reciprocating movement in the longitudinal and transverse directions, a pipe with a movable slide, made with the ability to regulate the air column, and a valve that allows opening and closing of the pipe, a lever mounted through a through hole in the upper part of the body and pivotally connected to each of the keys and spring-loaded to the body by means of two springs directed in opposite directions from the lever to the body, the upper end of the lever is connected to the rocker to transmit it back and forth translational movement in the longitudinal direction, the lower end of the lever is hinged on the key, the distal end of the key is mounted through the bar to the valve to transmit to it reciprocating movements in the vertical and transverse directions. 4. The keyboard for a musical instrument according to claim 3, characterized in that the upper part of the body is U-shaped. 5. A keyboard for a musical instrument according to claim 3, characterized in that the connection between the key and the bar is made using an eyelet in the bar and a pin with a head. 6. A keyboard for a musical instrument, containing a housing made in the form of upper and lower parts, between which, using rolling levers, the rolling axis of which is made in the middle part of the lever, keys are mounted with the ability to move them in the longitudinal direction due to the angular movement of the lever, with In this case, the lever is mounted through a through hole in the upper part of the body, a roller is mounted on the axis of rotation of the lever, on which a string rests, mounted with its end to the string tension bar, the upper end of the lever is connected by a spring to the spring tension bar with the ability to change the rigidity of the key, which is mounted pivotally to the lower end of the lever, the lever is equipped with a tension roller that interacts with the string in its section from the roller on which the string rests and the string tension bar, while the hinged connection of the key and the lever is made with the possibility of vertical reciprocating movement of the key along the lever to interact with the proximal ends potentiometers mounted in the lower part of the housing due to the swivel joint made in the lower part of the lever. 7. A keyboard for a musical instrument according to claim 6, characterized in that the string tension bars and springs are equipped with screws mounted through the wall of the case, the caps of which are located outside. 8. The keyboard for a musical instrument according to claim 6, characterized in that a protrusion is made in its lower part for interaction of the key with the potentiometer. 9. A keyboard for a musical instrument, containing a housing made in the form of upper and lower parts, between which keys rest on springs mounted in the lower part of the housing, at the distal ends of which counterweights are mounted, ensuring a shift of the center of gravity of the keys to the distal end, while the keys made with the possibility of displacement relative to the axis of the spring when acting on the proximal end of the key and back, after the end of the impact on the key due to the counterweight, while in the upper part of the body for each key, V-shaped recesses are provided, ensuring that the keys slide in them when they are displaced, in On the lower part of the keys, at the proximal end, there are sensors mounted that, when displaced, interact with their corresponding parts, mounted on the lower part of the housing under the sensors and causing the appearance of an electrical signal that is converted into an audio signal. 10. A keyboard for a musical instrument according to claim 9, characterized in that the spring is connected to the key and to the lower part of the body through supports.