JP2017026842A - Support assembly and keyboard device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce manufacturing cost of a support assembly, while suppressing the change in touch feeling during key operation, in comparison with a keyboard device of an acoustic piano.SOLUTION: A support assembly includes: a support disposed to be turned with respect to a frame; a jack connected to the support so as to be turned around a space between a large jack and a small jack; and a protrusion that protrudes from the large jack to a side opposite the small jack, to turn together with the jack, and comes into contact with the support on one side of a turning range of the jack.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a support assembly used in a keyboard device.

  Conventional acoustic pianos such as grand pianos and upright pianos are composed of many parts. Moreover, since the assembly of these parts is very complicated, it takes a long time to assemble. In particular, the action mechanism provided corresponding to each key requires many parts, and its assembling work is very complicated.

  For example, in the action mechanism shown in Patent Document 1, a plurality of parts interact with each other, and the key operation by key pressing and key release is transmitted to the hammer. In particular, the support assembly that forms part of the action mechanism operates in combination with various parts. The support assembly has not only a mechanism for realizing hammering by a hammer in response to a key press, but also an escapement mechanism for releasing a force transmitted to the hammer by the operation of the key immediately before the string is hit. This mechanism is an important mechanism for realizing the basic operation of an acoustic piano. In particular, a grand piano generally employs a double escapement mechanism in which a repetition lever and a jack are combined.

  The action mechanism provides a sense (hereinafter referred to as touch feeling) to the performer's finger through the key. In particular, the structure of the support assembly has an important influence on the touch feeling. For example, the touch feeling due to the operation of the escapement mechanism is called let-off.

JP 2005-292361 A

  Since the number of parts constituting the support assembly is large, the manufacturing period is prolonged and the manufacturing cost is increased. Therefore, in order to reduce the manufacturing cost, it is desired to simply reduce the number of parts or simplify the structure. However, when the configuration of the support assembly is changed, the touch feeling when operating the key is greatly changed. Therefore, it is difficult to reduce the manufacturing cost of an acoustic piano.

  One of the objects of the present invention is to reduce the manufacturing cost of a support assembly while suppressing a change in touch feeling when operating a key, as compared with a keyboard device of an acoustic piano.

  According to an embodiment of the present invention, a support that is rotatably arranged with respect to a frame, and a jack that is rotatably connected to the support with a center between a large jack and a small jack as a rotation center. A support assembly that protrudes from the large jack to the opposite side of the small jack, rotates together with the jack, and contacts with the support on one side of the rotation range of the jack. Is provided.

  You may further provide the elastic body which is connected to the said protrusion part and provides the rotational force to the said jack so that the said protrusion part may move to the said support side.

  You may further provide the guide part arrange | positioned at the both sides of the said protrusion part.

  According to an embodiment of the present invention, the plurality of support assemblies described above, a key disposed corresponding to each of the support assemblies, and a sound for rotating the support, and sounding in response to pressing of the key A sound generation mechanism is provided.

  When the key is at the rest position, the protrusion and the support may be in contact with each other.

  When the key is at the rest position, the protrusion and the support may not be in contact with each other.

  According to the embodiment of the present invention, it is possible to reduce the manufacturing cost of the support assembly while suppressing a change in touch feeling during key operation, as compared with an acoustic piano keyboard device.

It is a side view which shows the structure of the keyboard apparatus in 1st Embodiment of this invention. It is a side view which shows the structure of the support assembly in 1st Embodiment of this invention. It is a perspective view which shows the structure of the support assembly in 1st Embodiment of this invention. It is a side view which shows the one part structure which decomposed | disassembled the support assembly in 1st Embodiment of this invention. It is the figure which expanded the vicinity of the protrusion part of the support assembly in 1st Embodiment of this invention. It is the figure which expanded the vicinity of the 1st guide part of the support assembly in 1st Embodiment of this invention. It is a side view for demonstrating a motion of the support assembly in 1st Embodiment of this invention. It is a block diagram which shows the structure of the sound generation mechanism of the keyboard apparatus in 1st Embodiment of this invention. It is a side view which shows the structure of the support assembly in 2nd Embodiment of this invention.

  Hereinafter, a keyboard device including a support assembly according to an embodiment of the present invention will be described in detail with reference to the drawings. The following embodiments are examples of embodiments of the present invention, and the present invention should not be construed as being limited to these embodiments. Note that in the drawings referred to in the present embodiment, the same portion or a portion having a similar function is denoted by the same reference symbol or a similar reference symbol (a reference symbol simply including A, B, etc. after a number) and repeated. The description of may be omitted. In addition, the dimensional ratios of the drawings (the ratios between the components, the ratios in the vertical and horizontal height directions, etc.) may be different from the actual ratios for convenience of explanation, or some of the configurations may be omitted from the drawings.

<First Embodiment>
[Configuration of keyboard device 1]
The keyboard device 1 according to the first embodiment of the present invention is an example in which an example of a support assembly according to the present invention is applied to an electronic piano. This electronic piano has a structure close to a support assembly included in the grand piano in order to obtain a touch feeling close to that of the grand piano when operating keys. The outline of the keyboard apparatus 1 according to the first embodiment of the present invention will be described with reference to FIG.

  FIG. 1 is a side view showing a mechanical configuration of a keyboard apparatus according to an embodiment of the present invention. As shown in FIG. 1, the keyboard device 1 according to an embodiment of the present invention includes a plurality of keys 110 (88 keys in this example) and an action mechanism corresponding to each of the keys 110. The action mechanism includes a support assembly 20, a hammer shank 310, a hammer 320 and a hammer stopper 410. Although FIG. 1 shows the case where the key 110 is a white key, the same applies to a black key. Further, in the following description, terms representing directions such as the player's front side, the player's back side, the upper side, the lower side, and the side are defined as directions when the keyboard device is viewed from the player side. For example, in the example of FIG. 1, the support assembly 20 is disposed on the front side of the performer when viewed from the hammer 320 and is disposed above when viewed from the key 110. The side corresponds to the direction in which the keys 110 are arranged.

  The key 110 is rotatably supported by the balance rail 910. The key 110 rotates in the range from the rest position to the end position shown in FIG. Here, the “rest position” is a key position in a state where the key is not pressed, and the “end position” is a key position where the key is fully pressed. The key 110 includes a capstan screw 120. The support assembly 20 is rotatably connected to the support flange 290 and is placed on the capstan screw 120. The support flange 290 is fixed to the support rail 920. The detailed configuration of the support assembly 20 will be described later. The support flange 290 and the support rail 920 are examples of a frame that serves as a reference for rotation of the support assembly 20. The frame may be formed of a plurality of members such as the support flange 290 and the support rail 920, or may be formed of one member. The frame may be a rail-like member having a length in the arrangement direction of the keys 110 like the support rail 920, or may be a member independent for each key 110 like the support flange 290.

  The hammer shank 310 is pivotally connected to the shank flange 390. The hammer shank 310 includes a hammer roller 315. The hammer shank 310 is placed on the support assembly 20 via a hammer roller 315. The shank flange 390 is fixed to the shank rail 930. The hammer 320 is fixed to the end of the hammer shank 310. The regulating button 360 is fixed to the shank rail 930. The hammer stopper 410 is fixed to the hammer stopper rail 940 and is disposed at a position where the rotation of the hammer shank 310 is restricted.

  The sensor 510 is a sensor for measuring the position and moving speed of the hammer shank 310 (particularly, the speed immediately before the hammer shank 310 collides with the hammer stopper 410). The sensor 510 is fixed to the sensor rail 950. In this example, the sensor 510 is a photo interrupter. The output value from the sensor 510 changes according to the amount by which the shielding plate 520 fixed to the hammer shank 310 shields the optical axis of the photo interrupter. Based on this output value, the position and moving speed of the hammer shank 310 can be measured. Instead of the sensor 510 or together with the sensor 510, a sensor for measuring the operation state of the key 110 may be provided.

  The support rail 920, the shank rail 930, the hammer stopper rail 940, and the sensor rail 950 described above are supported by the bracket 900.

[Configuration of Support Assembly 20]
FIG. 2 is a side view showing the configuration of the support assembly in the first embodiment of the present invention. FIG. 3 is a perspective view showing the configuration of the support assembly in the first embodiment of the present invention. FIG. 4 is a side view showing a partial structure of the disassembled support assembly according to the first embodiment of the present invention. 4A is a view in which the jack 250 and the torsion coil spring 280 are excluded from the support assembly 20, and FIG. 4B is a view showing only the jack 250 so that the features of each component can be easily understood. is there.

  The support assembly 20 includes a support 210, a repetition lever 240, a jack 250, and a torsion coil spring 280. The support 210 and the repetition lever 240 are coupled via the flexible portion 220. The repetition lever 240 is supported by the flexible portion 220 so as to be rotatable with respect to the support 210. The support assembly 20 is a resin structure manufactured by injection molding or the like except for the cushioning material (nonwoven fabric, elastic body, etc.) provided at the portion that collides with the torsion coil spring 280 and other members. In this example, the support 210 and the repetition lever 240 are integrally formed. Note that the support 210 and the repetition lever 240 may be formed as separate parts and bonded or joined together.

  The support 210 has a through hole 2109 formed on one end side and a jack support portion 2105 formed on the other end side. The support 210 includes a support heel 212 protruding downward and a spring support 218 protruding upward between the through hole 2109 and the jack support 2105. The through hole 2109 passes through the shaft supported by the support flange 290. As a result, the support 210 is disposed so as to be rotatable with respect to the support flange 290 and the support rail 920. Accordingly, the through hole 2109 is the center of rotation of the support 210.

  The support heel 212 is in contact with the capstan screw 120 described above on its lower surface. The spring support 218 supports the torsion coil spring 280. The jack support part 2105 supports the jack 250 so that rotation is possible. For this reason, the jack support 2105 is the center of rotation of the jack 250.

  A space SP is formed on the jack support portion 2105 side of the support heel 212 between the through hole 2109 (the rotation center of the support 210) and the jack support portion 2105 (the rotation center of the jack 250). For convenience of explanation, the support 210 is divided into the first main body portion 2101, the bent portion 2102, and the second main body portion 2103 from the through-hole 2109 side. In this case, the second main body 2103 is arranged closer to the key 110 (downward) than the first main body 2101 by the bent portion 2102 that connects the first main body 2101 and the second main body 2103. The jack support 2105 protrudes upward from the second main body 2103. According to this section, the space SP corresponds to a region sandwiched between the bent portion 2102 and the jack support portion 2105 above the second main body portion 2103. A stopper 216 is coupled to the end of the support 210 (the end on the second main body 2103 side). The support heel 212 is disposed below the bent portion 2102. At this time, the distance from the key 110 to the second main body 2103 is preferably longer than the distance from the key 110 to the support heel 212 (that is, the length of the capstan screw 120). This makes it easier to adjust the capstan screw 120 from the player side.

  A spring contact portion 242 and an extending portion 244 are coupled to the repetition lever 240. The spring contact portion 242 and the extending portion 244 extend from the repetition lever 240 to the support 210 side. The spring contact portion 242 contacts the first arm 2802 of the torsion coil spring 280. The repetition lever 240 and the extending portion 244 include two plate-like members that are sandwiched from both sides of the jack 250. In this example, the extending portion 244 and the jack 250 are in sliding contact with each other in at least a part of the space sandwiched between the two plate-like members.

  The extending portion 244 includes an inner portion 2441, an outer portion 2442, a coupling portion 2443, and a stopper contact portion 2444. The inner portion 2441 is coupled to the player back side (flexible portion 220 side) with respect to the large jack 2502 in the repetition lever 240. A rib 246 is provided at a portion where the inner portion 2441 and the repetition lever 240 are coupled. The inside portion 2441 intersects with the jack large 2502 interposed therebetween, and extends to the player's front side (the side opposite to the flexible portion 220) from the jack large 2502. That is, it can be said that the extended portion 244 intersects the jack 250. The inner portion 2441 includes a linear convex portion P1 that protrudes toward the jack large 2502 side at a portion sandwiching the jack large 2502.

  The outer portion 2442 is coupled to the player's front side (opposite to the flexible portion 220) with respect to the jack 250 (jack size 2502) in the repetition lever 240. The inner portion 2441 and the outer portion 2442 are coupled at a coupling portion 2443. The coupling portion 2443 sandwiches the small jack 2504. The stopper contact portion 2444 is coupled to the coupling portion 2443 and contacts the stopper 216 from below the stopper 216. According to this, the stopper 216 restricts the rotation range of the repetition lever 240 in the direction (upward) in which the repetition lever 240 and the support 210 expand.

  The first guide part 215 includes a first member 2152 and a second member 2154 that protrude upward from the second main body part 2103. The first guide part 215 is disposed in the space SP. The second guide portion 211 includes a first member 2112 and a second member 2114 that protrude from the jack support portion 2105. When the jack 250 is viewed from the side, the first member 2112 and the second member 2114 are arranged so as not to overlap each other. In this example, the second member 2114 is smaller than the first member 2112. The detailed configuration of the first guide part 215 will be described later.

  The jack 250 includes a large jack 2502, a small jack 2504, and a protrusion 256. The jack 250 is disposed so as to be rotatable with respect to the support 210. Between the large jack 2502 and the small jack 2504, a support connecting portion 2505 is formed to be rotatably supported by the jack support portion 2105. The support connection portion 2505 has a shape surrounding a part of the jack support portion 2105 and restricts the rotation range of the jack 250. Further, the jack 250 can be fitted from above the jack support portion 2105 by the shape of the support connection portion 2505 and the elastic deformation of the material. The protruding portion 256 protrudes from the large jack 2502 to the opposite side of the small jack 2504 and rotates together with the jack 250. The protruding portion 256 includes a spring contact portion 2562 on its side surface. The spring contact portion 2562 contacts the second arm 2804 of the torsion coil spring 280.

  The large jack 2502 includes linear protrusions P2 protruding from both side surfaces. The convex portion P2 is in sliding contact with the convex portion P1 of the inner portion 2441 described above. The small jack 2504 includes a circular convex portion P3 protruding from both side surfaces. The convex portion P3 is in sliding contact with the inner surface of the coupling portion 2443 described above. Of the side surfaces of the jack 250, the support connection portion 2505 includes circular convex portions P4 and P5 around it. In this example, the convex portions P4 and P5 are present on the first member 2112 side of both side surfaces, and are not present on the second member 2114 side. The convex portions P4 and P5 are in sliding contact with the first member 2112 of the second guide portion 211 arranged around the jack support portion 2105.

  As described above, the jack 250 and the extended portion 244 are in sliding contact with each other via the convex portions P1, P2, and P3, thereby reducing the contact area. Further, the contact area is reduced by the sliding contact between the jack 250 and the second guide portion 211 (first member 2112) via the convex portions P4 and P5 arranged on the side surface of the jack 250. On the other hand, the jack 250 (around the support connection portion 2505) and the second member 2114 are in direct contact and are in sliding contact. In this example, since the second member 2114 has the same size as the convex portions P4 and P5, the contact area between the jack 250 (around the support connecting portion 2505) and the second member 2114 can be increased without providing the convex portion. You can keep it low. In addition, you may form a grease pool by forming a groove part by the some convex part P2. Further, the side surface shape of the large jack 2502 may have a convex portion or a groove portion.

  The torsion coil spring 280 uses the spring support portion 218 as a fulcrum, the first arm 2802 contacts the spring contact portion 242, and the second arm 2804 contacts the spring contact portion 2562. The first arm 2802 functions as an elastic body that applies rotational force to the repetition lever 240 via the spring contact portion 242 so that the player side of the repetition lever 240 moves upward (in a direction away from the support 210). The second arm 2804 functions as an elastic body that applies rotational force to the jack 250 via the spring contact portion 2562 so that the protruding portion 256 moves downward (on the support 210 side).

[Configuration of Protrusion 256]
FIG. 5 is an enlarged view of the vicinity of the protrusion of the support assembly according to the first embodiment of the present invention. In FIG. 5, components other than the jack 250 are indicated by broken lines. The position of the jack 250 when the key 110 is at the rest position (hereinafter sometimes referred to as the initial position) is as shown in FIG. As described above, the jack 250 is rotatably connected to the jack support portion 2105, and a force is applied by the second arm 2804 to rotate in the direction AS1. On the other hand, the large jack 2502 is in contact with the hammer roller 315 (see FIG. 1), thereby preventing the rotation in the direction AS1. As a result, the protrusion 256 and the second main body 2103 of the support 210 are in a state separated by a distance d.

  When the contact between the large jack 2502 and the hammer roller 315 is released, such as the state before the support assembly 20 is attached to the keyboard device 1, the turning force in the direction AS1 is received from the second arm 2804. As shown in FIG.5 (b), the protrusion 256 and the 2nd main-body part 2103 contact (refer area | region CA). As a result, the jack 250 cannot be rotated in the direction AS1. That is, one side of the rotation range of the jack 250 is defined by the contact position between the protruding portion 256 and the support 210 (second main body portion 2103).

  In this way, even if the time during which the hammer roller 315 and the large jack 2502 are separated from each other when the key is pressed becomes longer, the jack 250 is prevented from being greatly rotated in the direction AS1 by the force from the second arm 2804. be able to. Further, when the support assembly 20 is assembled, the position of the jack 250 with respect to the support 210 can be provisionally determined. Therefore, it is easy to adjust the positional relationship between the large jack 2502 and the hammer roller 315 after the support assembly 20 is attached to the support flange 290. For example, if the hammer shank 310 is lowered onto the support assembly 20 after the support assembly 20 is attached to the support flange 290, the hammer roller 315 abuts against the jack jack 2502, and the positional relationship between the jack jack 2502 and the hammer roller 315 is adjusted. Will be.

[Configuration of First Guide Part 215]
FIG. 6 is an enlarged view of the vicinity of the first guide portion of the support assembly according to the first embodiment of the present invention. FIG. 6A is an enlarged view of the vicinity of the first guide portion 215 shown in FIG. FIG. 6B is a diagram when the first guide portion 215 is viewed in the direction of the arrow A1 illustrated in FIG. FIG. 6C is a view when the first guide portion 215 is viewed in the direction of the arrow A2 shown in FIG. In FIGS. 6B and 6C, the configuration of the jack 250 (protruding portion 256) and the like are indicated by broken lines in order to show the positional relationship.

  The first member 2152 and the second member 2154 of the first guide part 215 protrude upward from the second main body part 2103 of the support 210 and are disposed on both sides of the protrusion part 256. When the protrusion 256 is viewed from the side (corresponding to FIG. 6A), the first member 2152 and the second member 2154 are arranged so as not to overlap. In this example, the first member 2152 and the second member 2154 are arranged so that the gap G shown in FIG. 6B is formed. According to such an arrangement, injection molding can be easily performed.

  The first member 2152 includes a linear first convex portion 2156. The first convex portion 2156 protrudes from the first member 2152 to the protruding portion 256 side at the end portion of the first member 2152 close to the second member 2154. As a result, the first member 2152 and the protruding portion 256 are in sliding contact with each other via the first convex portion 2156. The second member 2154 includes a linear second convex portion 2158. The second convex portion 2158 protrudes from the second member 2154 toward the protruding portion 256 at the end portion of the second member 2154 close to the first member 2152. As a result, the second member 2154 and the protruding portion 256 are in sliding contact with each other via the second convex portion 2158. The jack 250 is supported by the jack support portion 2105, and the protruding portion 256 and the first guide portion 215 (the first member 2152 and the second member 2154) are in sliding contact with each other, so that yawing of the jack 250 can be suppressed.

  Here, due to the presence of the protruding portion 256, the jack 250 and the first guide portion 215 can be slidably contacted with each other at a portion separated from the jack support portion 2105, so that yawing of the jack 250 can be efficiently suppressed.

  Further, in this example, the first contact is performed so that the spring contact portion 2562 (second arm 2804) disposed on the side surface of the protrusion 256 is close to the center in the width direction WD of the support 210 (second main body portion 2103). The position of the guide part 215 is arranged to be biased to one side of the second body part 2103 in the width direction WD. The above is the description of the configuration of the support assembly 20.

[Operation of Support Assembly 20]
Next, the movement of the support assembly 20 when the key 110 is pressed to the end position from the state where the key 110 is at the rest position (FIG. 1) will be described.

  FIG. 7 is a side view for explaining the movement of the support assembly in the first embodiment of the present invention. When the key 110 is pushed down to the end position, the capstan screw 120 pushes up the support heel 212 to rotate the support 210 around the axis of the through hole 2109. When the support 210 rotates and moves upward, the large jack 2502 pushes up the hammer roller 315 and the hammer shank 310 collides with the hammer stopper 410. In the case of a general grand piano, this collision is equivalent to hammering by a hammer.

  Immediately before the collision, the regulating button 360 restricts the upward movement of the small jack 2504 and further raises the support 210 (jack support portion 2105). Therefore, the large jack 2502 rotates so as to be detached from the hammer roller 315. At this time, the upward movement of the coupling portion 2443 is also restricted by the regulating button 360. In this example, the regulating button 360 also has a function of a repetition regulating screw in a general grand piano action mechanism.

  Thereby, the repetition lever 240 is rotated so that the upward movement is restricted and approaches the support 210. By these operations, a double escapement mechanism is realized. FIG. 7 is a diagram showing this state. When the key 110 is returned to the rest position, the hammer roller 315 is supported by the repetition lever 240, and the large jack 2502 is returned below the hammer roller 315. The turning force for returning the large jack 2502 to the lower side of the hammer roller 315 is provided by the second arm 2804 through the protrusion 256. At this time, even if the large jack 2502 returns to the lower side of the hammer roller 315 too early, the jack 250 may be rotated too much due to the contact between the protrusion 256 and the support 210 (second main body 2103). Can be suppressed.

  As described above, since the double escapement is realized in an easier configuration than a support assembly used in a general grand piano, the manufacturing cost can be reduced while suppressing the influence on the touch feeling.

[Sound generation mechanism of keyboard device 1]
The keyboard device 1 is an application example to an electronic piano as described above, and measures the operation of the key 110 by the sensor 510 and outputs a sound corresponding to the measurement result.

  FIG. 8 is a block diagram showing the configuration of the sound generation mechanism of the keyboard device according to the first embodiment of the present invention. The sound generation mechanism 50 of the keyboard device 1 includes a sensor 510 (sensors 510-1, 510-2,... 510-88 corresponding to 88 keys 110), a signal conversion unit 550, a sound source unit 560, and an output unit 570. . The signal conversion unit 550 acquires the electrical signal output from the sensor 510, generates an operation signal corresponding to the operation state of each key 110, and outputs the operation signal. In this example, the operation signal is a MIDI signal. Therefore, the signal conversion unit 550 outputs note-on corresponding to the timing when the hammer shank 310 collides with the hammer stopper 410 by the key pressing operation. At this time, the key number indicating which of the 88 keys 110 has been operated and the velocity corresponding to the velocity immediately before the collision are also output in association with the note-on. On the other hand, when the key release operation is performed, in the case of a grand piano, the signal conversion unit 550 outputs the key number and the note-off in association with each other at the timing when the vibration of the string is stopped by the damper. A signal corresponding to another operation such as a pedal may be input to the signal conversion unit 550 and reflected in the operation signal. The sound source unit 560 generates a sound signal based on the operation signal output from the signal conversion unit 550. The output unit 570 is a speaker or a terminal that outputs the sound signal generated by the sound source unit 560.

Second Embodiment
In the first embodiment, when the jack 250 is in the initial position, the protruding portion 256 and the support 210 (second main body portion 2103) are separated from each other. In the second embodiment, an example in which the protruding portion 256 and the support 210 (second main body portion 2103) are in contact with each other when the jack 250 is in the initial position will be described.

  FIG. 9 is a side view showing the configuration of the support assembly in the second embodiment of the present invention. FIG. 9A is a side view of the support assembly 20A when the jack 250A is in the initial position. FIG. 9B is an enlarged view of the vicinity of the protruding portion 256A. As shown in FIG. 9B, when the jack 250A is in the initial position, the projecting portion 256A and the second main body portion 2103 come into contact with each other (see the area CA). That is, the jack 250A is prevented from rotating in the direction AS2 from the initial position. At this time, the jack 250 </ b> A may not be in contact with the hammer roller 315.

<Modification>
In each embodiment mentioned above, the convex part was arrange | positioned at the one or both of the structure which mutually slidably contacts. In the case of being arranged in any one of the configurations, it may be arranged in any configuration. For example, in the first embodiment, the first convex portion 2156 is disposed on the first member 2152, but may be disposed on the protruding portion 256 instead of the first member 2152. Even in this case, the first member 2152 and the protruding portion 256 are in sliding contact with each other via the first convex portion. In addition, a mutual structure may come into sliding contact without using a convex part (a 1st convex part and a 2nd convex part are included).

  In the above-described embodiment, the first member 2152 and the second member 2154 of the first guide portion 215 are disposed on both sides of the protruding portion 256. However, even if the first member 2152 or the second member 2154 is not present. Good. For example, if the first member 2152 exists, yawing in one direction (on the first member 2152 side with respect to the protruding portion 256) can be suppressed even if the second member 2154 does not exist.

  In the first embodiment described above, the protruding portion 256 is disposed in the space SP. On the other hand, even if the shape of the support 210 is a shape that does not form the space SP, the protrusion is disposed above the support, and the protrusion and the support come into contact with each other by the rotation of the jack. Good. The second embodiment can be similarly modified.

  In each embodiment mentioned above, the electronic piano was shown as an example of the keyboard apparatus to which the support assembly was applied. On the other hand, the support assembly of the above embodiment can also be applied to a grand piano (acoustic piano). In this case, the sound generation mechanism corresponds to a hammer and a string.

DESCRIPTION OF SYMBOLS 1 ... Keyboard apparatus, 20 ... Support assembly, 50 ... Sound generating mechanism, 110 ... Key, 120 ... Capstan screw, 210 ... Support, 211 ... 2nd guide part, 212 ... Support heel, 215 ... 1st guide part, 216 ... Stopper, 218 ... Spring support part, 220 ... Flexible part, 240 ... Repetition lever, 242 ... Spring contact part, 244 ... Extension part, 246 ... Rib, 250 ... Jack, 256 ... Projection part, 280 ... Coil spring, 290 ... support flange, 310 ... hammer shank, 315 ... hammer roller, 320 ... hammer, 360 ... regulating button, 390 ... shank flange, 410 ... hammer stopper, 510 ... sensor, 520 ... shielding plate, 550 ... signal converter, 560 ... Sound source unit, 570 ... output unit, 900 ... bracket 910 ... Balance rail, 920 ... Support rail, 930 ... Shank rail, 940 ... Hammer stopper rail, 950 ... Sensor rail, 2101 ... First body part, 2102 ... Bending part, 2103 ... Second body part, 2105 ... Jack support part 2109 ... through hole, 2112 ... first member, 2114 ... second member, 2152 ... first member, 2154 ... second member, 2156 ... first convex portion, 2158 ... second convex portion, 2441 ... inner portion, 2442 ... Outer part, 2443 ... Coupling part, 2444 ... Stopper contact part, 2502 ... Large jack, 2504 ... Small jack, 2505 ... Support connection part, 2562 ... Spring contact part, 2802 ... First arm, 2804 ... Second arm

Claims (6)

A support arranged to be rotatable with respect to the frame;
A jack that is pivotally connected to the support, with the jack large and the jack small as a pivot center;
A protruding portion that protrudes from the large jack to the opposite side of the small jack and rotates together with the jack, and a protruding portion that contacts the support on one side of the rotating range of the jack;
A support assembly comprising:   2. The support assembly according to claim 1, further comprising an elastic body connected to the protrusion and imparting a turning force to the jack so that the protrusion moves toward the support. 3.   The support assembly according to claim 1, further comprising guide portions disposed on both sides of the protruding portion. A plurality of support assemblies according to any of claims 1 to 3;
A key disposed corresponding to each of the support assemblies for rotating the support;
A sounding mechanism that sounds in response to pressing of the key;
A keyboard device comprising:   The keyboard apparatus according to claim 4, wherein the protrusion and the support are in contact with each other when the key is at a rest position.   The keyboard device according to claim 4, wherein the protrusion and the support are not in contact when the key is at a rest position.

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