JP3896972B2 - Keyboard device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a keyboard device used for a keyboard instrument such as an electronic piano.
[0002]
[Prior art]
Conventionally, in a keyboard instrument such as an electronic piano, in order to obtain a key touch feeling similar to the key touch feeling of an acoustic piano, a hammer arm having a weight portion is provided on the lower side of the key so as to be pivotable in the vertical direction. When the key is pressed, the hammer arm rotates against the weight of its weight, so that a predetermined action load is applied to the key, and the key load is increased in the low frequency range of the key. There is one in which the key load in the sound range is reduced (for example, see Patent Document 1).
In addition, in order to obtain a key touch feeling similar to that of an acoustic piano, a keyboard instrument such as an electronic piano applies a predetermined action load to the key when the key is pressed by a hammer arm having a weight portion. In some cases, a so-called let-off effect is obtained in which a key load is drastically reduced near the deepest position at the time of keying to give a click feeling that the key is pulled out (see, for example, Patent Document 2).
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 10-240232
[Patent Document 2]
JP-A-6-230770
[0004]
[Problems to be solved by the invention]
In the keyboard instrument of Patent Document 1, in order to change the key load between the low range and the high range of the key, a support shaft is provided inside the key, and one end portion of the hammer arm is rotatably attached to the support shaft. A hammer support portion that rotatably supports the hammer arm on the keyboard chassis is provided so as to be movable in the longitudinal direction of the hammer arm, and the hammer arm that is provided to the key by appropriately moving the hammer support portion in the longitudinal direction of the key. Changing the load.
However, in such a keyboard instrument, in order to change the key load between the low range and high range of the key, a hammer support must be provided on the keyboard chassis in a movable manner, which not only complicates the structure. Further, there is a problem that a dedicated part for moving and fixing the hammer support part is required, the number of parts is increased, and the assembling work becomes complicated.
[0005]
Further, in the keyboard instrument of Patent Document 2, a leaf spring is provided behind a hammer arm that rotates in accordance with a key pressing operation in order to provide a let-off effect by abruptly reducing the key load near the deepest position at the time of key pressing. If the rear end of the hammer arm comes into contact with the contact portion of the elastic body when the key is pressed, the elastic body is provided with a contact portion such as a roller that contacts the rear end of the hammer arm. Since the elastic body is elastically deformed and the rear end portion of the hammer arm gets over the contact portion, the key load is drastically reduced in the vicinity of the deepest position when the key is pressed.
However, in such a keyboard instrument, even if a let-off effect can be imparted, a leaf spring-like elastic body must be provided behind the hammer arm, and a contact portion such as a roller must be provided on this elastic body. The structure is complicated, the number of parts is large, and when the hammer arm rotates with the key-pressing operation, the rear end of the hammer arm must abut against the abutting part to be elastically deformed. , There is a problem that the position adjustment is troublesome and the assembly workability is also poor.
[0006]
The first problem of the present invention is that the key load can be changed between the high frequency range and the low frequency range of the key with a simple structure, thereby reducing the number of parts and a key that approximates the key touch feeling of an acoustic piano. It is to obtain a touch feeling.
[0007]
In addition, the second problem of the present invention is that it has a simple structure and can provide a let-off effect in which the key load is drastically reduced in the vicinity of the deepest position at the time of key depression, thereby reducing the number of parts and assembling workability. The aim is to improve the key touch feeling similar to that of an acoustic piano.
[0008]
[Means for Solving the Problems]
  In order to solve the above problems, the present invention includes the following components.
  In addition, the reference numerals of the drawings attached to the respective elements described in the section of each embodiment described later are attached to the respective constituent elements together with parentheses.
  As shown in FIGS. 1 to 10, the invention described in claim 1 includes a keyboard chassis (1), a plurality of keys (2) arranged on the keyboard chassis so as to be rotatable in the vertical direction, and these A keyboard device comprising a hammer arm (3) arranged corresponding to each of a plurality of keys and pivotally displaced in accordance with a key pressing operation of the key to apply an action load to the key. Extend the projecting part (40) to the bottom of the key.An upper first guide groove (44, 55) and a lower second guide groove (45, 56) are provided substantially in parallel along the longitudinal direction of the key, and a hammer projection (29b) is provided at one end of the hammer arm. And a hammer projection of the hammer arm corresponding to a key belonging to the high frequency range among the plurality of keys is movably inserted into the first guide groove when the key is depressed, and a key belonging to the low frequency range is The corresponding hammer projection of the hammer arm is inserted into the second guide groove so as to be movable when the key is pressed.This is a keyboard device.
[0009]
According to the present invention, one end portion of the hammer arm is movably guided by the upper hammer guide portion (first hammer guide groove 44) among the plurality of hammer guide portions provided in the key extension portion. In the first case and in the second case where one end of the hammer arm is movably guided by the lower hammer guide portion (second hammer guide groove 45), the one end of the hammer arm is moved up and down. Each distance (L1, L2) from each position (P1, P2) contacting the hammer guide portion (first and second hammer guide grooves 44, 45) to the key rotation center (key support shaft 22) is different. As a result, a difference occurs in the rotational moment of the key between the first case and the second case, whereby the key load can be changed between the first case and the second case.
[0010]
That is, since the upper hammer guide groove and the lower hammer guide groove have different heights at the extending portion, for example, one end portion of the high-pitched hammer arm is connected to the upper hammer guide portion (first hammer guide groove 44). ) And the second case in which one end of the low-pitched hammer arm is guided by the lower hammer guide portion (second hammer guide groove 45), the first case in the high sound range. Is shorter than the distance (L2) in the second case of the low range (L1 <L2), so that the rotational moment of the key in the first case on the high range side is the second on the low range side. Therefore, the key load at the time of key depression in the first case of the high sound range can be made lighter than that in the second case of the low sound range, which makes it closer to the key touch feeling of the acoustic piano. It is possible to obtain the key touch feeling.
[0011]
  In this way, since it is only necessary to provide a plurality of hammer guide portions in the key extension portion substantially parallel to the longitudinal direction of the key, the structure is simple, and a plurality of hammer guide portions provided in the key extension portion are also provided. Since it is only necessary to guide one end of the hammer arm with one of the hammer guides, the key load can be easily changed between the high range and the low range, so that the entire range from the high range to the low range can be changed. Parts such as a key and a hammer arm can be used in common, so that the number of parts can be reduced and a product with good assembling workability can be obtained.
  In particular, since a plurality of hammer guide portions are provided in the extending portion, the first case in which one end portion of the hammer arm is movably guided by the hammer guide portion located on the upper side among the plurality of hammer guide portions, In the second case where one end of the hammer arm is movably guided by the hammer guide portion located on the side, the key load can be changed by changing the rotational moment of the key. Since the key load can be changed depending on the sound range, a key touch feeling similar to that of an acoustic piano can be obtained.
[0012]
  As shown in FIGS. 11 to 15, the invention described in claim 2The first and second guide grooves (55, 56) are formed in a shape in which a guide surface on which a hammer projection of the hammer arm slides when the key is pressed protrudes downward from the key. The claim according to claim 1It is a keyboard device.
[0013]
According to the present invention, since one end of the hammer arm is movably guided by the hammer guide provided in the key extension, when the key is depressed to displace the extension downward, Along with this, one end of the hammer arm is guided downward by the hammer guide part while being pushed downward. At this time, the action load applied to the key by the hammer guide part can be changed. By forming the shape into a desired shape, it is possible to give a let-off effect in which the key load is drastically reduced near the deepest position when pressing the key, thereby providing a key touch feeling that approximates the key touch feeling of an acoustic piano. Obtainable. For this reason, since it is only necessary to provide a hammer guide part along the longitudinal direction of the key in the key extension part, the structure is simple, and a dedicated part for giving a let-off effect as in the prior art is unnecessary. The number of parts can be greatly reduced and a product with good assembly workability can be obtained.
[0014]
  In particular according to the invention,The guide surface on which one end of the hammer arm slides when the key is pressed is formed in a shape that protrudes downward from the key, so that one end of the hammer arm moves along the guide surface when the key is pressed. The key load can be increased until it reaches the convex tip of the surface, that is, the lowest part, and the key load decreases drastically when the convex tip of the guide surface is overcome. Since the key load is drastically reduced in the vicinity of the deepest position and a click feeling that can be pulled out of the key can be imparted, the let-off effect can be obtained satisfactorily.
[0016]
  Claim3As shown in FIGS. 1 to 15, the invention described in FIG. 1 includes a key guide portion (43) guided by the key guide (9) of the keyboard chassis (1) to the extension portion (40), and the The upper limit stopper portion (46) for restricting the upper limit position of the key (2) is provided.1It is a keyboard apparatus as described in above.
  According to the present invention, if the key guide portion is provided in the key extension portion, the key guide portion is guided by the key guide of the keyboard chassis, so that it is possible to prevent the key from shaking. Since the horizontal swing of the hammer arm can be prevented, the key and the hammer arm can be smoothly operated in the vertical direction. Further, if the upper limit stopper portion is provided in the key extension portion, even if the hammer arm rotates by its own weight and urges the key upward, the upper limit stopper portion of the extension portion causes the key to be Since the upper limit position can be restricted, the key and the hammer arm can always be restricted to a predetermined initial position when the key is not pressed.
[0017]
  Claim41 to 15, the hammer arm (3) is provided with a rotating portion (30), and the rotating portion includes a plurality of rotating central portions (first to first). 3 locking recesses 34 to 36) are provided along the longitudinal direction of the hammer arm, and any one of the plurality of rotation center portions is rotatably supported by the keyboard chassis (1). Claims1It is a keyboard apparatus as described in above.
  According to the present invention, by appropriately selecting any one of a plurality of rotation center portions provided in the rotation portion of the hammer arm and supporting the hammer arm with respect to the keyboard chassis 1, Since the rotational moment can be changed, the key load by the hammer arm can be changed easily and easily, and this can also change the key load between the high and low range of the key. A key touch feeling similar to that of an acoustic piano can be obtained.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
[First Embodiment]
Hereinafter, a first embodiment of a keyboard apparatus according to the present invention will be described with reference to FIGS.
As shown in FIGS. 1 to 3, the keyboard apparatus includes a synthetic resin keyboard chassis 1 and a plurality of synthetic resin keys (white keys) provided on the keyboard chassis 1 so as to be rotatable in the vertical direction. And a black key, but here a white key will be described.) 2, a hammer arm 3 that applies an action load to each of the plurality of keys 2, and a rubber that outputs an ON signal in response to a key pressing operation of each key 2. And a switch 4.
[0019]
As shown in FIGS. 1 to 3, the keyboard chassis 1 constitutes a lower case of the instrument body, and a front cover corresponding to the front end surface of the key 2 is provided at the front end (right end in FIG. 3). The part 5 is formed so as to protrude upward from the bottom part. A lower limit stopper 7 such as a felt for restricting the lower limit position of the key 2 is provided on the upper part of the middle step part 6 at the rear part of the front cover part 5. Further, on the rear side of the front cover portion 5, a guide placement portion 8 is formed with a height that is approximately half the height of the front cover portion 5. A key guide 9 for preventing the lateral movement of the key 2 is formed on the upper portion of the guide mounting portion 8 so as to stand substantially vertically from a tip portion protruding toward the rear (left side in FIG. 3) of the key 2. Has been. Furthermore, an upper limit stopper 10 such as a felt for restricting the upper limit position of the key 2 is provided on the lower surface of the upper portion of the guide mounting portion 8.
[0020]
Moreover, as shown in FIG. 3, the front side reinforcement part 11 and the hammer mounting part 12 for ensuring the intensity | strength of the keyboard chassis 1 are formed in the front part side in the intermediate part of the keyboard chassis 1 at the front and back. . The hammer mounting portion 12 is formed to have a height that is approximately half the height of the guide mounting portion 8, and a hammer support portion 13 is formed on the upper surface thereof. As shown in FIG. 5, the hammer support portion 13 has a structure in which support protrusions 13 b are provided to face each other on opposing surfaces of a pair of support pieces 13 a that face each other. Further, as shown in FIG. 3, mounting bosses 14 are suspended from the lower surface of the guide mounting portion 8 and the lower surface of the hammer mounting portion 12, respectively. The bottom plate 15 on the front side that continuously covers the bottom portions of the portion 8, the front reinforcing portion 11, and the hammer placement portion 12 is attached by screws 16.
[0021]
Further, a rear reinforcing portion 17 for securing the strength of the keyboard chassis 1 is formed on the rear side of the intermediate portion of the keyboard chassis 1. A plurality of support bosses 18 are formed higher than the guide placement portion 8 at predetermined positions of the rear reinforcing portion 17. On these support bosses 18, a switch board 19 for mounting the rubber switch 4 is screwed. Further, as shown in FIG. 3, a key holding portion 20 is formed at the rear portion of the keyboard chassis 1 substantially the same as or slightly lower than the front cover portion 5, and a key support portion 21 is formed on the upper surface thereof. Is formed. The key support portion 21 is provided with a key support shaft 22 for rotatably supporting the rear end portion (left end portion in FIG. 3) of the key 2. In this case, the front leg portion 23 of the key holding portion 20 is provided with an opening 24 into which the rear end portion of the hammer arm 3 is inserted. An attachment boss 25 is also suspended from the key holding portion 20, and a rear bottom plate 26 that closes the bottom of the key holding portion 20 is attached to the lower end portion of the attachment boss 25 by screws 16. .
[0022]
On the other hand, as shown in FIGS. 1 to 3, the hammer arm 3 has an arm main body 27 disposed on the upper side of the intermediate portion of the keyboard chassis 1 and a rear end portion (left end portion in FIG. 3) of the arm main body 27. Provided at the weight portion 28 provided, the key abutting portion 29 provided at the front end portion (right end portion in FIG. 3) of the arm main body 27, and the portion located on the rear side of the key abutting portion 29 in the arm main body 27. The rotation part 30 was provided. The hammer arm 3 has a weight portion 28 inserted into the opening 24 of the front leg portion 23 of the key holding portion 20 of the keyboard chassis 1 from above the keyboard chassis 1, and the key abutting portion 29 is inserted into the keyboard. It is arranged below the key guide 7 of the chassis 1, and in this state, the rotating part 30 is configured to be attached to the hammer support part 13 of the keyboard chassis 1 so as to be rotatable in the vertical direction.
[0023]
In this case, as shown in FIG. 4, the key abutting portion 29 includes a shaft portion 29a protruding in the left-right direction of the front end portion of the arm main body 27 (that is, the arrangement direction of the hammer arms 3), and both end portions of the shaft portion 29a. And a hammer projection 29b formed on the surface. Further, as shown in FIGS. 3 and 5, the rotating portion 30 has a substantially elliptical plate portion 31 that is inserted between the pair of support pieces 13 a of the hammer support portion 13. On both surfaces of the plate portion 31, guide grooves 32 into which the support protrusions 13 b of the hammer support portion 13 are movably inserted are provided along the longitudinal direction of the hammer arm 3. An insertion / removal groove 33 through which the support protrusion 13b is detachably inserted is provided across the lower end surface of 31.
[0024]
Further, in these guide grooves 32, as shown in FIGS. 3 and 5, first to third locking recesses 34 to 36 into which the support protrusions 13 b are detachably inserted extend along the longitudinal direction of the hammer arm 3. Are provided at predetermined intervals. That is, among the first to third locking recesses 34 to 36, the first locking recess 34 is provided at the rear end portion (the left end portion in FIGS. 3 and 5) of the guide groove 32, and the second locking recess 35. Is provided at an intermediate portion of the guide groove 32, and the third locking recess 36 is provided at a front end portion (right end portion in FIGS. 3 and 5) of the guide groove 32. Thereby, the rotation part 30 is inserted into any one of the first to third locking recesses 34 to 36 by the support protrusion 13b of the hammer support part 13 of the keyboard chassis 1 so that the first to third locking recesses. The hammer arm 3 is configured to rotate up and down around any one of 34 to 36.
[0025]
Thereby, the hammer arm 3 is in a state in which the support protrusion 13b of the hammer support portion 13 of the keyboard chassis 1 is inserted into any of the first to third locking recesses 34 to 36 of the rotating portion 30, for example, FIG. As shown, when the support protrusion 13b of the hammer support portion 13 is rotatably supported while being inserted into the second locking recess 35 of the rotation portion 30, the rear of the hammer arm 3 is usually driven by the weight of the weight portion 28. The end portion is urged downward, whereby the entire hammer arm 3 rotates counterclockwise in FIG. 1 to urge the key contact portion 29 on the front end side upward, and the key 2 is counterclockwise in FIG. It is comprised so that it may urge around.
[0026]
As shown in FIGS. 1 to 3, the key 2 is provided with key attachment holes 37 on both side surfaces of the rear end portion (left end portion in FIG. 3), and the key attachment holes 37 support the key of the keyboard chassis 1. It is rotatably attached to a key support shaft 22 provided in the portion 21, and is thereby configured to rotate up and down around the key support shaft 22. A switch pressing portion 39 for pressing the rubber switch 4 of the switch board 19 attached on the support boss 18 of the rear reinforcing portion 17 of the keyboard chassis 1 is formed in the intermediate portion of the key 2. Further, an extension 40 protrudes below the key 2 at a position on the front side (right side in FIG. 3) of the switch pressing portion 39 in the key 2, that is, a position corresponding to the key guide 9 of the keyboard chassis 1. It is extended.
[0027]
As shown in FIGS. 1 to 4, the extending portion 40 is formed such that a pair of side plate portions 41 protrudes below the key guide 9 of the keyboard chassis 1, and between the rear end portions of the pair of side plate portions 41. A reinforcing plate portion 42 is formed from the upper portion of the key 2 to substantially the middle portion (between the left end portions in FIG. 3). As shown in FIG. 1, a key guide portion 43 into which the key guide 9 of the keyboard chassis 1 is inserted is surrounded by a reinforcing plate portion 42 and a side plate portion 41 at the upper portion of the extending portion 40. Yes. Further, first and second hammer guide grooves 44 and 45 for guiding the hammer protrusion 29b of the hammer arm 3 are formed in the vertical direction below the key guide portion 43 in the extending portion 40. Further, as shown in FIG. 1, an upper limit stopper portion 46 that restricts the upper limit position of the key 2 is formed to protrude toward the front side (right side in FIG. 3) of the key 2, as shown in FIG. 1. .
[0028]
In this case, as shown in FIGS. 3 and 4, the first and second hammer guide grooves 44, 45 are formed in the longitudinal direction of the key 2 in a state where they face each other on the opposing surfaces of the pair of side plate portions 41 of the extending portion 40. It is formed along the direction. That is, the first hammer guide groove 44 is positioned above the second hammer guide groove 45, is formed in a straight line substantially parallel to the key pressing surface of the key 2, that is, the upper surface of the key 2, and the keys 2 arranged in the order of the scales. The hammer projection 29b of the hammer arm 3 corresponding to the high-frequency range key 2 is inserted movably. The second hammer guide groove 45 is positioned below the first hammer guide groove 44, is formed in a straight line substantially parallel to the first hammer guide groove 44, and is the lower of the keys 2 arranged in the order of the scale. The hammer projection 29b of the hammer arm 3 corresponding to the key 2 in the sound range is configured to be inserted.
[0029]
Further, as shown in FIG. 3, the upper limit stopper portion 46 is formed to project forward from the front side (right side in FIG. 3) between the lower end portions of the pair of side plate portions 41, and this projecting portion is the keyboard chassis 1. The guide mounting portion 8 is inserted into the opening 47 formed in the rear leg portion 8a. In this state, the guide mounting portion 8 moves up and down in the opening 47 in response to a key pressing operation. By abutting the upper limit stopper 10 from below, the upper limit position of the key 2 is regulated and the lower limit position of the weight portion 28 of the hammer arm 3 is also regulated. As shown in FIGS. 1 to 3, a lower limit stopper portion 48 that is in contact with the lower limit stopper 7 of the keyboard chassis 1 from above is formed at the lower front end of the key 2.
[0030]
As a result, the extended portion 40 is urged upward by the key abutting portion 29 of the hammer arm 3 and the upper limit stopper formed on the lower end portion of the extended portion 40 is normally provided as shown in FIG. When the portion 46 comes into contact with the upper limit stopper 10 of the keyboard chassis 1 from below, the position of the key 2 is restricted to the upper limit position that is the initial position, and the weight portion 28 of the hammer arm 3 is restricted to the lower limit position that is the initial position. Is configured to do. When the key 2 is pressed against the weight of the weight portion 28 of the hammer arm 3, a lower limit stopper portion 48 formed at the lower portion of the front end portion of the key 2 is provided as shown in FIG. By contacting the lower limit stopper 7 of the keyboard chassis 1 from above, the key 2 is restricted to a predetermined lower limit position, and the weight portion 28 of the hammer arm 3 is restricted to a predetermined upper limit position.
[0031]
As shown in FIGS. 1 to 3, the rubber switch 4 includes a rubber sheet disposed on the upper surface of the switch substrate 19, and a dome-like bulge portion is provided on the rubber sheet and the switch pressing portion 39 of each key 2. The movable contact is provided in the bulging portion, and the movable contact is opposed to the fixed contact on the switch board 19 so as to be separated from the fixed contact. When the bulging portion is pressed by the switch pressing portion 39, the bulging portion is elastically deformed so that the movable contact comes into contact with the fixed contact, thereby outputting an ON signal.
[0032]
Next, the case where such a keyboard apparatus is assembled will be described.
In this case, as shown in FIG. 3, the base plates 15 and 26 are respectively attached to the bottom of the keyboard chassis 1 in advance. Thereafter, the hammer arm 3 is placed on the keyboard chassis 1. At this time, the weight portion 28 of the hammer arm 3 is inserted into the opening 24 of the front leg portion 23 of the key holding portion 20 of the keyboard chassis 1, and the key abutting portion 29 is placed under the key guide 9 of the keyboard chassis 1. In this state, any one of the first to third locking recesses 34 to 36 of the rotating portion 30 is rotatably attached to the support protrusion 13b provided on the hammer support portion 13 of the keyboard chassis 1. And after attaching the switch board 19 on the support boss | hub 18 provided in the intermediate part of the keyboard chassis 1, the key 2 is attached on the keyboard chassis 1 from the upper direction.
[0033]
At this time, first, the key guide 9 of the keyboard chassis 1 is inserted into the key guide portion 43 provided at the upper portion of the extension portion 40 of the key 2, and the upper limit stopper portion 46 provided at the lower portion of the extension portion 40 is provided. It is inserted into the opening 47 formed in the rear leg portion 8a of the guide mounting portion 8 of the keyboard chassis 1 so as to correspond to the lower side of the upper limit stopper 10, and in this state, the extended portion 40 of the key 2 is provided. The hammer protrusion 29b of the key contact portion 29 of the hammer arm 3 is inserted into either the first or second hammer guide portion 44 or 45. In this case, the hammer protrusion 29b of the hammer arm 3 corresponding to the key 2 in the high pitch range among the keys 2 arranged in the musical order is arranged on the upper first hammer guide groove 44 as shown in FIGS. Insert into. Further, the hammer protrusion 29b of the hammer arm 3 corresponding to the key 2 in the low sound range is inserted into the lower second hammer guide groove 45 as shown in FIGS.
[0034]
As a result, when the hammer protrusion 29b of the key abutting portion 29 of the hammer arm 3 is inserted into one of the first and second hammer guide grooves 44 and 45 provided in the extending portion 40 of the key 2, The contact portion 29 is slidably held by one of the first and second hammer guide grooves 44 and 45. In this state, the switch pressing portion 39 of the key 2 is made to correspond to the rubber switch 4 of the switch board 19, and the key mounting hole 37 at the rear end portion of the key 2 is connected to the key support shaft 21 a of the key support portion 21 of the keyboard chassis 1. Attach to the top and bottom so that it can rotate. Thereby, the key 2 and the hammer arm 3 are attached to the keyboard chassis 1 so as to be rotatable in the vertical direction.
[0035]
Next, the operation of the keyboard device assembled in this way will be described.
In this case, all the hammer arms 3 corresponding to the keys 2 arranged in the musical order are arranged in the middle part of the rotating part 30 among the first to third locking recesses 34 to 36 of the rotating part 30. It is assumed that the second locking recess 35 located is rotatably supported by the support protrusion 13b of the hammer support portion 13 of the keyboard chassis 1. Of the keys 2 arranged in the scale order, the high-frequency range key 2 is a first hammer guide in which the hammer protrusion 29b of the key abutting portion 29 of the hammer arm 3 is the key 2 as shown in FIGS. The bass key 2 is slidably inserted into the groove 44, and the hammer protrusion 29b of the hammer arm 3 slides into the second hammer guide groove 45 of the key 2 as shown in FIGS. Inserted as possible. Therefore, in the following, the case of the high-frequency range key 2 and the case of the low-frequency range key 2 will be described in order.
[0036]
First, in the case of a high sound range, as shown in FIG. 1, the hammer protrusion 29 b of the key contact portion 29 of the hammer arm 3 is formed in the upper first hammer guide groove 44 provided in the extension portion 40 of the key 2. Normally, the hammer arm 3 is urged counterclockwise in FIG. 1 by the weight of the weight portion 28, so that the key abutting portion 29 of the hammer arm 3 moves up the extended portion 40 of the key 2. Therefore, the upper limit stopper portion 46 of the key 2 contacts the upper limit stopper 10 of the keyboard chassis 1 from below. For this reason, the key 2 is restricted to the upper limit position which is a predetermined initial position, and the weight portion 28 of the hammer arm 3 is restricted to the predetermined lower limit position. In this state, when the key 2 is pressed against the weight of the weight portion 28 of the hammer arm 3, the key 2 rotates clockwise around the key support shaft 21a at the rear end as shown in FIG. Move.
[0037]
At this time, since the key guide portion 43 of the extension portion 40 of the key 2 is guided by the key guide 9 of the keyboard chassis 1, the extension portion 36 of the key 2 smoothly moves downward without causing the key 2 to sway. Moving. At the same time, the hammer projection 29b of the hammer arm 3 inserted into the first hammer guide groove 44 of the extension portion 40 of the key 2 is pushed down by the extension portion 40 of the key 2, so that the hammer projection 29b of the hammer arm 3 is While sliding in the first hammer guide groove 44 of the key 2, the hammer arm 3 rotates clockwise in FIG. 1 around the second locking recess 35 of the rotating portion 30 of the hammer support shaft 31. Thereby, since the action load according to the weight of the weight part 28 of a hammer arm is given to the key 2, the key touch feeling approximated to the key touch feeling of an acoustic piano can be obtained.
[0038]
In the case of the low frequency range, as shown in FIG. 6, the lower second hammer guide groove 45 in which the hammer protrusion 29 b of the key abutting portion 29 of the hammer arm 3 is provided in the extending portion 40 of the key 2. The hammer arm 3 is normally urged counterclockwise in FIG. 6 by the weight of the weight portion 28 as in the case of the high sound range, so that the key abutting portion 29 of the hammer arm 3 is locked to the key. Since the two extending portions 40 are urged upward, the upper limit stopper portion 46 of the key 2 contacts the upper limit stopper 10 of the keyboard chassis 1 from below. For this reason, the key 2 is restricted to the upper limit position which is a predetermined initial position, and the weight portion 28 of the hammer arm 3 is restricted to the predetermined lower limit position. In this state, when the key 2 is depressed against the weight of the weight portion 28 of the hammer arm 3, the key 2 rotates clockwise around the key support shaft 21a at the rear end portion as shown in FIG. Move.
[0039]
Also at this time, since the key guide portion 43 of the extension portion 40 of the key 2 is guided by the key guide 9 of the keyboard chassis 1, the extension portion 36 of the key 2 can be smoothly moved without causing the key 2 to sway. Move down. At the same time, the hammer projection 29b of the hammer arm 3 inserted into the second hammer guide groove 45 provided in the extension part 40 of the key 2 is pushed down by the extension part 40 of the key 2, so that the hammer of the hammer arm 3 While the protrusion 29 b slides in the second hammer guide groove 45 of the key 2, the hammer arm 3 rotates clockwise in FIG. 6 about the second locking recess 35 of the hammer support shaft 31. Thereby, since the action load according to the weight of the weight part 28 of a hammer arm is given to the key 2, the key touch feeling approximated to the key touch feeling of an acoustic piano can be obtained.
[0040]
In this case, the key load of each key 2 is different between the high sound range and the low sound range. That is, in the initial state where the key 2 is not depressed, each key 2 of the high sound range and the low sound range has the hammer protrusion 29b of the hammer arm 3 in the extended portion 40 of the key 2 as shown in FIG. Since the distances L1 and L2 from the positions P1 and P2 in contact with the first and second hammer guide grooves 44 and 45 to the key support shaft 22 that is the rotation center of the key 2 are different, the key load of each key 2 is different. F will be different. That is, the distances S1 and S2 from the second locking recess 35 of the rotating portion 30 that is the rotation center of the hammer arm 3 to the hammer projection 29b have the same length (S1 = S2), but in the extended portion 40. Since the heights of the first and second hammer guide grooves 44 and 45 are different, the position P1 where the high-pitched hammer protrusion 29b contacts the first hammer guide groove 44 and the low-pitched hammer protrusion 29b are the second hammer guide groove. The height differs from the position P <b> 2 in contact with 45.
[0041]
For this reason, the high frequency range L1 from the position P1 where the high frequency hammer projection 29b contacts the first hammer guide groove 44 to the key support shaft 22 which is the rotation center of the key 2, and the low frequency hammer projection 29b Unlike the distance L2 in the low range from the position P2 in contact with the second hammer guide groove 45 to the key support shaft 22 that is the rotation center of the key 2, the high range L1 is shorter than the low range L2 ( L1 <L2). For this reason, the rotational moment of the high-frequency range key 2 is smaller than the rotational moment of the low-frequency range key 2, so that the key load F on the high-frequency range side during key depression is lighter than the key load F on the low-frequency range side. . Moreover, even if each key 2 rotates in this manner, as shown in FIG. 8B, the high range L1 and the low range L2 approach each other, but the distance L1 becomes longer than the distance L2. Therefore, even when the key 2 rotates, the key load in the high sound range is the same as or lighter than that of the key 2 in the low sound range.
[0042]
When the key 2 rotates and the hammer arm 3 rotates as described above, the switch pressing portion 39 of the key 2 presses the rubber switch 4 as shown in FIGS. 2 and 7, and the rubber switch 4 is turned on, the lower limit stopper portion 48 at the front end portion of the key 2 comes into contact with the lower limit stopper 7 of the front cover portion 5 of the keyboard chassis 1 from above, whereby the rotation of the key 2 and the hammer arm 3 is stopped. . Thereafter, the hammer arm 3 is rotated in the direction opposite to the above by the weight of the weight portion 28. Accordingly, the key 2 is also rotated in the direction opposite to the above, whereby the key 2 and the hammer arm 3 are rotated. Returns to the initial position shown in FIGS.
[0043]
By the way, in this keyboard apparatus, the key load in the low sound range can be further increased. In this case, as shown in FIG. 9, among the first to third locking recesses 34 to 36 provided in the rotating portion 30 of the hammer arm 3, a hammer is placed in the third locking recess 36 on the front side. The support protrusion 13b of the support portion 13 is inserted to support the hammer arm 3, and the hammer arm 3 may be rotated about the third locking recess 36. When the third locking recess 36 is supported by the hammer support portion 13 in this way, the distance from the third locking recess 36 that is the rotation center of the hammer arm 3 to the weight portion 28 is the first and second locking. Since the recesses 34 and 35 are longer than the center of rotation, the rotational moment of the hammer arm 3 is increased, thereby increasing the key load.
[0044]
Further, in order to lighten the key load in the bass range, as shown in FIG. 10, the rear side of the first to third locking recesses 34 to 36 provided in the rotating portion 30 of the hammer arm 3 is arranged. The support protrusion 13b of the hammer support portion 13 is inserted into the first locking recess 34 to support the hammer arm 3, and the hammer arm 3 may be rotated about the first locking recess 34. When the first locking recess 34 is supported by the hammer support portion 13 in this way, the distance from the first locking recess 34 that is the rotation center of the hammer arm 3 to the weight portion 28 is the second and third locking. Since the recesses 35 and 36 are shorter than the center of rotation, the rotational moment of the hammer arm 3 is reduced, thereby reducing the key load.
[0045]
On the other hand, when the key load in the high sound range is further reduced, the first to third locking recesses 34 to 36 provided in the rotating portion 30 of the hammer arm 3 are performed as in the case of the low sound range shown in FIG. In this case, the support protrusion 13b of the hammer support portion 13 is inserted into the first locking recess 34 on the rear side so that the hammer arm 3 can be pivotally supported. Conversely, when the key load in the high sound range is increased. Is the third locking recess 36 on the front side among the first to third locking recesses 34 to 36 provided in the rotating portion 30 of the hammer arm 3 as in the case of the bass range shown in FIG. It is only necessary to insert the support protrusion 13b of the hammer support portion 13 and to support the hammer arm 3 so as to be rotatable.
[0046]
As described above, according to this keyboard device, of the first and second hammer guide grooves 44 and 45 provided in the extending portion 40 of the key 2, the upper hammer guide arm 44 has a high-pitched hammer arm. A high-frequency range in which the third hammer projection 29b is slidably inserted, and a low-frequency range in which the hammer projection 29b of the low-frequency hammer arm 3 is slidably inserted into the lower second hammer guide groove 45. Thus, the distances L1 and L2 from the positions P1 and P2 at which the hammer projection 29b of the hammer arm 3 contacts the first and second hammer guide grooves 44 and 45 to the key support shaft 22 which is the rotation center of the key 2 are made different. Accordingly, the distance L1 on the high frequency range side can be made shorter (L1 <L2) than the distance L2 on the low frequency range side, so that the rotational moment of the key 2 on the high frequency range side is made smaller than that on the low frequency range side. Can Yellow, it can be lighter than the bass side of the key load of this for treble side.
[0047]
Thus, the first and second hammer guide grooves 44 and 45 need only be provided along the longitudinal direction of the key 2 in the extending portion 40 of the key 2, so that not only the structure is simple but also the extension of the key 2 is extended. Simply inserting the hammer protrusion 29b of the key abutting portion 29 of the hammer arm 3 into one of the first and second hammer guide grooves 44, 45 provided in the protruding portion 40, the key load in the high range and the low range Since the key load can be changed easily and easily, the parts such as the key 2 and the hammer arm 3 can be made common throughout the entire sound range from the high range to the low range. The number of points can be reduced, and a product with good assembly workability can be obtained.
[0048]
Further, in this keyboard apparatus, the extension part 44 of the key 2 is provided with a key guide part 43 guided by the key guide 9 of the keyboard chassis 1 and an upper limit stopper part 46 for regulating the upper limit position of the key 2. Since the key guide portion 43 is guided by the key guide 9 of the keyboard chassis 1, it is possible to prevent the key 2 from sideways and thereby prevent the hammer arm 3 from sideways. 2 and the hammer arm 3 can be smoothly moved in the vertical direction, and even if the hammer arm 3 is rotated by the weight of the weight portion 28 to urge the extension portion 40 of the key 2 upward, the key Since the upper limit position of the key 2 is restricted by the upper limit stopper part 46 provided in the second extension part 40, the key 2 and the hammer arm 3 can always be restricted to a predetermined initial position when the key is not pressed.
[0049]
Further, in this keyboard device, the first to third locking recesses 34 to 36 are provided at predetermined intervals along the longitudinal direction of the hammer arm 3 in the rotating portion 30 of the hammer arm 3. Since any one of the locking recesses 34 to 36 is rotatably supported by the support protrusion 13b of the hammer support portion 13 of the keyboard chassis 1, any one of the first to third locking recesses 34 to 36 is appropriately selected. Then, the key load applied to the key 2 by the hammer arm 3 can be changed by rotatably supporting the support projection 13b of the hammer support portion 13, and this also allows the high frequency range and low frequency range of the key 2 to be changed. Since the key load can be changed, it is possible to obtain a key touch feeling more similar to the key touch feeling of an acoustic piano.
[0050]
[Second Embodiment]
Next, a second embodiment of the keyboard device of the present invention will be described with reference to FIGS. The same parts as those in the first embodiment shown in FIG. 1 to FIG.
This keyboard device has a structure in which a hammer guide groove 50 for providing a click feeling to the key 2 when a key is depressed is provided at a position located between the key guide portion 43 and the upper limit stopper portion 46 in the extending portion 40 of the key 2. The rest of the structure is almost the same as that of the first embodiment. That is, as shown in FIGS. 12 and 13, the hammer guide groove 50 guides the hammer protrusion 29 b of the key abutting portion 29 of the hammer arm 3 so as to be movable, and a pair of side plates of the extending portion 40. The opposing surface of the portion 41 is formed along the longitudinal direction of the key 2. In this case, a guide surface 51 is formed on the upper side surface of the hammer guide groove 50 so that the hammer protrusion 29b contacts and moves when the key is pressed, and the lower side surface facing this is the key pressing surface of the key 2, that is, the key 2 It is formed in a straight line substantially parallel to the upper surface of.
[0051]
As shown in FIG. 13, such a guide surface 51 is formed in an inverted mountain shape that protrudes downward from the key 2. That is, the guide surface 51 is formed on the first inclined surface 51a whose rear side (left side in the figure) is gently inclined toward the front lower portion of the key 2, and the front side is more than the first inclined surface 51a. A steeply inclined second inclined surface 51b is formed, and a front end portion of the second inclined surface 51b is formed on a third inclined surface 51c that is abruptly inclined in the opposite direction, that is, toward the front upper side of the key 2. As a result, the guide surface 51 is pressed in the direction of being pushed up by the hammer projection 29b when the key is pressed, and the hammer projection 29b slides from the rear side toward the front side along the first inclined surface 51a, When the hammer projection 29b slides toward the front side along the second inclined surface 51b, and the hammer projection 29b climbs over the lowermost portion 51d of the second inclined surface 51b, the hammer projection 29b rapidly rises along the third inclined surface 51c. Is configured to do.
[0052]
Next, the operation at the time of key depression in this keyboard apparatus will be described.
Normally, as shown in FIG. 11, the key abutment portion 29 of the hammer arm 3 biases the extension portion 40 of the key 2 upward by the weight of the weight portion 28 of the hammer arm 3, so that the upper limit of the key 2 is increased. The stopper portion 46 comes into contact with the upper limit stopper 10 of the keyboard chassis 1 from below, so that the key 2 is restricted to the upper limit position, which is a predetermined initial position, and the weight portion 28 of the hammer arm 3 is restricted to the predetermined lower limit position. The When the key 2 is pressed against the weight of the weight portion 28 of the hammer arm 3 in this state, the key 2 rotates clockwise in FIG. 11 around the key support shaft 22 at the rear end thereof. Accordingly, the hammer arm 3 is supported by the support protrusion 13b of the hammer support portion 13 while the hammer protrusion 29b of the key contact portion 29 of the hammer arm 3 is guided along the hammer guide groove 50 of the extension portion 40 of the key 2. The second locking recess 35 of the rotating unit 30 rotates clockwise in FIG.
[0053]
At this time, since the weight of the weight portion 28 of the hammer arm 3 is applied to the key 2, as shown in FIG. 14, the key load increases suddenly, and when the point K1 shown in FIG. Although it is substantially constant, the hammer protrusion 29b of the key abutting portion 29 slides along the first inclined surface 51a of the guide surface 51 of the hammer guide groove 50, so that the key load gradually increases. In this state, when the key 2 is further pushed down and reaches the point K2 shown in FIG. 14, the switch pressing portion 39 of the key 2 presses the rubber switch 4, and the hammer projection 29b of the key abutting portion 29 is guided by the guide surface. Since it slides along 51 2nd inclined surface 51b, a key load rises rapidly.
[0054]
Then, when the key 2 is pushed down to a position near the deepest point and reaches the point K3 shown in FIG. 14, the hammer projection 29b of the hammer arm 3 is in the second inclined surface with the switch pressing portion 39 pressing the rubber switch 4. Since it moves over the lowermost part 51d of 51b and rapidly moves upward along the third inclined surface 51c, the key load is suddenly reduced toward the point K4 shown in FIG. As a result, a click feeling that is lost to the key 2 is given, and a let-off effect is obtained. Thereafter, when the key 2 is further pushed down and reaches the point K5 from the point K4 shown in FIG. 14, the hammer projection 29b comes into contact with the uppermost part of the third inclined surface 51c and the lower limit stopper at the front end of the key 2 Since the portion 48 abuts against the lower limit stopper 7 of the keyboard chassis 1 from above, the key load suddenly increases again, and when the point K5 shown in FIG. 14 is reached, the rotation of the key 2 and the hammer arm 3 is temporarily stopped.
[0055]
When the key is released, the hammer arm 3 is rotated counterclockwise in FIG. 11 by the weight of the weight portion 28, and the hammer protrusion 29 b of the hammer arm 3 is guided by the hammer guide groove 50 of the key 2 accordingly. Since the key 2 is pushed up, the key 2 rotates counterclockwise in FIG. At this time, since the key 2 is in a substantially free state, the key load is suddenly reduced from the point K5 to the point K6 shown in FIG. Then, when the point K6 shown in FIG. 14 is reached, the hammer protrusion 29b passes over the lowermost part 51d of the second inclined surface 51b of the guide surface 51, and the key 2 is pushed up by the elastic return force of the rubber switch 4. Is a little heavy. Thereafter, when the point K7 shown in FIG. 14 is reached, the hammer projection 29b slides along the first inclined surface 51a without being affected by the rubber switch 4, so that the key load is gently reduced. Then, when the point K8 shown in FIG. 14 is reached, the key load suddenly decreases again, the upper limit stopper portion 46 of the key 2 comes into contact with the upper limit stopper 10 of the keyboard chassis 1 from below, and the key 2 and the hammer arm 3 are rotated. The movement stops and the key 2 and the hammer arm 3 return to the initial positions.
[0056]
Thus, according to this keyboard device, when the hammer projection 29b of the hammer arm 3 is guided by the guide surface 51 of the hammer guide groove 50 when the key is depressed, the hammer projection 29b forms an inverted mountain shape of the guide surface 51. Since it slides along the first to third inclined surfaces 51a to 51c, the key load becomes heavy until the hammer projection 29b reaches the lowermost portion 51d of the second inclined surface 51b, but the second inclined surface When the lowermost 51d of 51b is overcome, the key load is drastically reduced, and a click feeling that feels coming out of the key 2 can be imparted, whereby a letoff effect can be imparted near the deepest position at the time of key depression. . Further, when the key is released, the key contact portion 29 of the hammer arm 3 is not significantly affected by the second and third inclined surfaces 51b and 51c and the lowermost portion 51d of the guide surface 51 of the hammer guide groove 50. There is little change and the key 2 can be smoothly returned to the initial position. For this reason, it is possible to obtain a key touch feeling more similar to the key touch feeling of an acoustic piano.
[0057]
In the second embodiment, the case where one extension guide 40 of the key 2 is provided with one hammer guide groove 50 has been described. However, the present invention is not limited to this, and as shown in FIG. A structure in which the guide grooves 55 and 56 are provided substantially in parallel along the longitudinal direction of the key 2 may be used. According to such a structure, as in the first embodiment, the upper first hammer guide groove 55 guides the hammer protrusion 29a of the high-frequency hammer arm 3 and the lower second hammer guide groove 56 reduces the height. By guiding the hammer protrusion 29a of the hammer arm 3 on the sound range side, the key load can be changed between the high-frequency key 2 and the low-frequency key 2 as in the first embodiment.
Also in the second embodiment, any one of the first to third locking recesses 34 to 36 of the rotating portion 30 of the hammer arm 3 can be rotated by the support protrusion 13 b of the hammer supporting portion 13 of the keyboard chassis 1. The key load can be changed as appropriate, as in the first embodiment.
[0058]
In the modification of the first embodiment and the second embodiment, the case where two first and second hammer guide grooves 44, 45 or 55, 56 are provided in the extending portion 40 of the key 2 has been described. However, the present invention is not limited to this. For example, three or four or more hammer guide grooves may be provided. For example, if three hammer guide grooves are provided, the key load of the middle range can be changed as well as the high range and low range of the key 2, and if four or more are provided, the high range and mid range can be changed. And the bass range can be further divided and the key load can be changed more finely according to each range.
[0059]
【The invention's effect】
As described above, according to the first aspect of the present invention, a plurality of hammer guide portions are provided in the key extension portion substantially in parallel along the longitudinal direction of the key, and any one of the plurality of hammer guide portions is provided. In the first case where one end of the hammer arm is movably guided by the hammer guide portion located on the upper side, and the hammer guide portion located on the lower side. With the second case where one end of the hammer arm is movably guided, the distance from the position where the one end of the hammer arm contacts the upper and lower hammer guides to the center of rotation of the key is varied. As a result, there is a difference in the rotational moment of the key between the first case and the second case, so that the key load can be changed between the first case and the second case.
[0060]
For this reason, for example, the rotational moment of the key in the first case where one end portion of the high-pitched hammer arm is guided by the upper hammer guide portion, and one end portion of the low-pitched hammer arm is guided by the lower hammer guide portion. Since the rotation moment of the key 2 in the second case can be made smaller, the key load on the high sound side can be made lighter than the key load on the low sound side, which makes the key touch feeling of an acoustic piano An approximate key touch feeling can be obtained. Thus, it is only necessary to provide a plurality of hammer guide portions in the key extension portion in parallel with the longitudinal direction of the key, so that not only the structure is simple, but also a plurality of hammer guide portions provided in the key extension portion. Just by guiding one end of the hammer arm with one of the hammer guides, the key load can be changed easily and easily between the high and low ranges, so the key can be changed over the entire high and low range. In addition, it is possible to share parts such as a hammer arm and the like to reduce the number of parts and to obtain an assembly workability good.
[0061]
According to the second aspect of the present invention, the hammer guide portion that changes the action load applied to the key by movably guiding one end portion of the hammer arm to the key extension portion along the longitudinal direction of the key. As a result, when the key is pressed and the extension portion is displaced downward, one end of the hammer arm is guided downward by the hammer guide portion while being pushed downward. Since the action load applied to the key can be changed, by forming the shape of the hammer guide portion into a desired shape, a let-off effect is provided in which the key load is drastically reduced near the deepest position during key pressing. Thus, a key touch feeling similar to that of an acoustic piano can be obtained. For this reason, since it is only necessary to provide a hammer guide part along the longitudinal direction of the key in the key extension part, the structure is simple, and a dedicated part for giving a let-off effect as in the prior art is unnecessary. The number of parts can be greatly reduced and a product with good assembly workability can be obtained.
[0062]
In this case, particularly in the hammer guide portion, a guide surface that guides one end portion of the hammer arm when the key is pressed is formed in a convex shape toward the lower side of the key. The key load can be increased until the part moves along the guide surface and reaches the convex tip of the guide surface, that is, the lowest part. Since it becomes lighter rapidly, the key load is rapidly reduced near the deepest position at the time of key depression, and a click feeling that feels coming out of the key can be given, so that a let-off effect can be obtained with certainty.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a high-frequency region side in a first embodiment of a keyboard device according to the present invention.
FIG. 2 is a cross-sectional view showing a state where the key of FIG. 1 is pressed.
3 is a cross-sectional view showing an exploded state of the keyboard device of FIG. 1. FIG.
4 is an enlarged cross-sectional view of a key extension portion as viewed in the direction of arrows AA in FIG. 3;
FIG. 5 is an enlarged cross-sectional view of a rotating portion of the hammer arm as viewed in the direction of arrows BB in FIG.
6 is a cross-sectional view showing a low-frequency region side in the keyboard device of FIG. 1. FIG.
7 is a cross-sectional view showing a state where the key of FIG. 6 is pressed. FIG.
FIGS. 8A and 8B show the principle of the key rotation moment in the high range and low range of FIGS. 1 and 6, wherein FIG. 8A shows the initial state, and FIG. 8B shows the state when the key is pressed; Figure.
9 is a cross-sectional view showing a state in which the rotation center of the hammer arm is set to the third locking recess in the keyboard device of FIG. 6. FIG.
10 is a cross-sectional view showing a state in which the rotation center of the hammer arm is set to the first locking recess in the keyboard device of FIG. 9;
FIG. 11 is a cross-sectional view showing a second embodiment of the keyboard device of the present invention.
12 is a cross-sectional view showing the key of FIG.
13 is an enlarged view of the hammer guide groove of FIG.
14 is a diagram showing a relationship between a key load and a key stroke in the keyboard device of FIG.
FIG. 15 is a diagram showing a modification of the key according to the second embodiment.
[Explanation of symbols]
1 Keyboard chassis
2 keys
3 hammer arm
9 Key guide
13 Hammer support
13b Support protrusion
21 Key support
22 Key support shaft
27 Arm body
28 weight
29 Key contact
29b Hammer projection
30 Rotating part
34-36 First to third locking recesses
37 Key mounting hole
40 Extension
43 Key guide
44, 45 First and second hammer guide grooves
46 Upper limit stopper
48 Lower limit stopper
50 Hammer guide groove
51 Guide surface
51a-51c 1st-3rd inclined surface
51d Lowermost part of second inclined surface
55, 56 1st and 2nd hammer guide grooves

Claims (4)

A keyboard chassis, a plurality of keys arranged on the keyboard chassis so as to be rotatable in the vertical direction, and arranged corresponding to each of the plurality of keys; In a keyboard device comprising a hammer arm that applies an action load to the key,
An extension portion is extended from the key so as to protrude below the key, and an upper first guide groove and a lower second guide groove are substantially parallel to the extension portion along the longitudinal direction of the key. And providing a hammer projection on one end of the hammer arm,
Among the plurality of keys, the hammer projection of the hammer arm corresponding to the key belonging to the high frequency range is movably inserted into the first guide groove when the key is pressed, and the hammer corresponding to the key belonging to the low frequency range A keyboard device , wherein a hammer protrusion of an arm is inserted into the second guide groove so as to be movable when a key is pressed . The first and second guide grooves are formed such that a guide surface on which a hammer projection of the hammer arm slides when the key is pressed is convex toward the lower side of the key. Item 1. The keyboard device according to Item 1 . 2. The extension part is provided with at least one of a key guide part guided by a key guide of the keyboard chassis and an upper limit stopper part for regulating an upper limit position of the key. The keyboard device described . The hammer arm is provided with a rotation portion, and the rotation portion is provided with a plurality of rotation center portions along the longitudinal direction of the hammer arm, and any one of the plurality of rotation center portions is the keyboard. The keyboard device according to claim 1, wherein the keyboard device is rotatably supported by the chassis .

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