JP4682943B2 - Keyboard device - Google Patents

Description

  The present invention relates to a keyboard device used for an electronic keyboard instrument such as an electronic organ, an electronic piano, a synthesizer, or an electric keyboard instrument.

  Conventional keyboard devices used for electronic keyboard instruments such as electronic organs and electronic pianos include a comb-shaped keyboard device as disclosed in Patent Document 1, for example. In this keyboard device, a plurality of key body portions to be pressed are connected to a key common holding portion extending in a key arranging direction via a thin connecting portion, and each key body portion is swingably held in the key pressing direction. These are integrally molded with resin to form a comb-like key unit. Then, for example, every other octave key range, a white key unit consisting of four white keys, a white key unit consisting of the remaining three white keys, and a black key consisting of five black keys. Formed separately into units, the key common holding parts are overlapped and fixed together and fixed to the key mounting part of the keyboard frame with screws (screws), and connected to the required key range to constitute the keyboard device .

With such a configuration, it is not necessary to provide a fulcrum portion on the keyboard frame, and since a plurality of keys are integrated into a unit, the number of parts is small, assembly and maintenance are easy, and it is extremely effective in reducing manufacturing costs.
However, it is necessary to provide a key guide for each key so as to regulate the position of each key in the key arrangement direction and prevent sideways shaking when the key is pressed.

  Therefore, as can be seen in Patent Document 2, some comb-type keyboard devices do not require a key guide. This is because the overall width in the key width direction of the connecting portion in each key unit as described above is wider than the width of the rear end of the key body portion, and the key has sufficient flexibility in the direction of pressing and releasing keys. Increase the moment of inertia of the cross section for the force in the width direction (lateral direction). As a result, it is possible to regulate the lateral movement (yawing) of the key body in the key width direction without using the key guide, and the keyboard device can be manufactured at low cost.

Also, the keyboard device of an electronic musical instrument is provided with a mass body such as a hammer corresponding to each key so that a touch feeling with a feeling of weight similar to the key touch feeling of a natural musical instrument such as a piano can be obtained. For example, Patent Document 3 discloses a technique in which a desired key pressing touch feeling is obtained by swinging in conjunction with the key pressing operation of each key and applying a force corresponding to the movement as a reaction to the key pressing force. Has been practiced conventionally.
JP-A-6-342281 Japanese Patent Laid-Open No. 7-92963 Japanese Patent No. 2917863

However, in the comb-type keyboard device as shown in Patent Document 1, it is necessary to provide a key guide for each key, so that the keyboard device as a whole cannot sufficiently simplify the structure. There is a problem that it takes time to adjust the position of the key guide.
Therefore, if each key unit is configured to be found in Patent Document 2, a key guide can be made unnecessary. However, when assembling the keyboard device by stacking the key common holding portions of a plurality of key units, it is necessary that a part of each key connecting portion overlaps with a neighboring key connecting portion in a plane. It is necessary to make the width in the key width direction sufficiently wide. Otherwise, it will be necessary to provide a key guide at the key free end. This complicates the shape and keyboard structure of each key unit, increases the molding cost, and increases design constraints.

  further. If it is a mini keyboard whose key length is shorter than that of the standard keyboard, even with such a structure, the lateral swing of the key body can be sufficiently restricted by the wide connecting part, but in the case of the standard keyboard, the key body part Because of the long length, it is difficult to sufficiently regulate the lateral movement of the key body (especially the white key) only with the wide connecting portion, and the glissando playing method is difficult to perform and the performance is poor. Arise.

  In addition, in a keyboard apparatus provided with a mass body that is linked to each key as found in Patent Document 3, a key guide for each key, a key switch, a linkage mechanism between the key and the mass body (hammer), Since there are many members to be placed under the key, such as a lower limit stopper, a keyboard device that can obtain a desired touch feeling can be provided at low cost under many restrictions on the shape, arrangement, and movable range of the mass body. It was extremely difficult to design.

  The present invention has been made to solve the various problems as described above. While reducing the number of components of the keyboard device and simplifying the assembly to reduce the cost, the black key and the white key can be swayed. The purpose of this is to increase the degree of freedom of design even when a mass body interlocking with each key is provided.

The present invention is a keyboard device in which a plurality of keys are provided in the key attachment portion of a key attachment member, and each key of the plurality of keys is operated to be depressed, and each key body portion is attached to the key attachment portion. A key having a key common holding part that is commonly held in a swingable manner relative to the part, and a coupling part for holding each key body part in the key common holding part so as to be able to swing in the direction of pressing and releasing keys. In order to achieve the above-mentioned object, a keyboard device comprising units is configured as follows.
The key unit is divided into a white key unit in which each key is a white key and a black key unit in which each key is a black key. ,

The length of the key body in the longitudinal direction of the white key is longer than that of the black key, and the black key unit has a total width in the key arrangement direction of the connecting portion that is larger than the key width of the key body of the black key. In addition, the connecting portion restricts the rocking in the key width direction when the black key is pressed and released.
The white key unit is configured such that the full width of the connecting portion in the key arranging direction is narrower than the full width of the connecting portion of the black key unit in the key arranging direction, and the white key is free to swing in the key arranging direction on the free end side. A guide portion is provided to restrict and guide the key movement.

  Alternatively, instead of configuring the white key unit in the key arrangement direction of the connecting portion in the key arrangement direction narrower than the entire width of the key arrangement direction of the black key unit in the key arrangement direction, or in such a configuration, You may comprise so that a key width direction rocking | fluctuation permission part may be provided.

In addition, it can be configured such that a part of the black key connecting portion overlaps with the adjacent white key connecting portion.
Further, the guide portion of the white key is provided at the tip of the white key that is longer than the black key and is likely to wobble, and the guide member provided on the key attachment portion facing the tip of the white key; If it is configured, the guide of the white key is guided, so that the key does not wobble.

  Alternatively, in the keyboard device, each of the black key connecting portions has an overlapping portion that partially overlaps the adjacent key connecting portion, and a portion of the overlapping portion is behind the key body portion of the white key. An escape portion is formed at the rear end portion of the key body portion of the white key, and is configured to overlap the upper surface of the end portion, and the height of the upper surface of the rear end portion is set lower than the other portions of the key body portion. When the keyboard device is configured by superimposing the black key on the white key, a part of the connecting portion of the black key may be fitted to the escape portion of the white key.

In these keyboard devices, the black key connecting portion is composed of a thin-walled hinge portion that enables key-release key rotation and a thick-walled connecting portion that is stiffer than the thin-walled hinge portion, and the thick-walled connecting portion is the key body. It is good to comprise so that it may extend back from the rear-end part of a part, it may be connected with the said thin hinge part, and it may couple | bond with the said key common holding | maintenance part via the thin hinge part.
The thick connection portion may protrude from the side surface of the rear end portion of the key body portion toward the adjacent key and extend rearward.

  Moreover, these keyboard apparatuses may be a keyboard apparatus provided with a mass body that is driven by a driving unit provided below each of the plurality of keys, and a mass body attaching portion that attaches each mass body.

In that case, it is desirable to provide driving units for driving the mass bodies respectively below the free end portions of the white keys and the black keys.
Further, a part of the overlapping portion of the black key connecting portion overlaps the upper surface of the rear end portion of the key body portion of the white key, and the height of the upper surface is increased to the rear end portion of the key body portion of the white key. It is preferable to form a relief part having a lower height than the other parts, so that a part of the overlapping part overlaps therewith.

  In the keyboard device according to the present invention, since the black key has a short length in the longitudinal direction, the width of the connecting portion is widened to regulate the swing of the key body portion in the key width direction without the guide portion, and the white key is in the longitudinal direction. Since the length of the connecting portion is long, the width of the connecting portion is not widened, or the connecting portion has a key width direction swing allowing portion, and a guide portion is provided on the free end side of the key main body portion so as to extend in the key width direction. Since the shaking is restricted, the lateral movement of both the black key and the white key can be surely restricted while reducing the number of components of the keyboard device and simplifying the assembly and reducing the cost.

Also, by making the rear end of the key body of the white key overlap with a part of the connection part of the black key, the white key connection part is shortened to increase the rigidity of the key body part. The key body of the key can be prevented from bending. In addition, since the key body of the white key and the black key is lengthened, it can be made close to a parallel key and easy to play.
Then, by forming a relief portion for the black key connecting portion on the upper surface of the rear end portion of the white key main body portion, a portion of the black key connecting portion is fitted to the cut portion, so that the key rear end The height of the part can be held down. In addition, the degree of freedom in mounting design related to the vicinity of the fulcrum of the key can be improved.
The black key connecting part is composed of a thin hinge part and a rigid thick connecting part, and the thick connecting part extends rearward from the rear end part of the key body part and is connected to the thin hinge part. The rigidity against yawing can be increased by coupling to the key common holding portion via the thin hinge portion.
By projecting the thick connection portion from the rear end portion of the key body portion in the adjacent key direction, the yawing force applied to the black key can be more firmly regulated.

Furthermore, even when a mass body that is linked to each key is provided, the degree of freedom in design can be increased, and a design that can provide a desired touch feeling is facilitated.
In particular, it is not necessary to provide a guide part near the free end of the black key by making the connecting part (hinge part) of the black key wide and restricting rolling without the guide part. A space for arranging necessary parts can be easily secured, the degree of freedom in mounting design is improved, and the key and the mass body are easily assembled. Therefore, it is possible to realize a keyboard device with a mass body at low cost.

Hereinafter, the best mode for carrying out the present invention will be specifically described with reference to the drawings.
FIG. 1 to FIG. 10 are views showing an embodiment of the present invention. FIG. 1 is a schematic cross-sectional view of the electronic musical instrument having the keyboard device according to the present invention along the longitudinal direction of the key, and FIG. 2 is one octave of the keyboard device. FIG. 3 is a front view seen from the direction of arrow S in FIG. 1, and FIG. 4 is a bottom view of the free end side of the white key.

FIG. 5 is a plan view showing only the key units constituting the keyboard device, with the white key unit indicated by a solid line and the black key unit indicated by a virtual line. FIG. 6 is an enlarged side view showing the vicinity of the key common holding portion of the key unit, and FIG. 7 is a perspective view showing the vicinity of the key attachment portion of the keyboard frame and a part of the first white key unit attached thereto. FIG. 8 is a perspective view of a part of the black key unit as viewed from below.
FIG. 9 is a plan view showing the keyboard device shown in FIG. 2 with the key unit and the switch board removed and a part thereof broken away, and FIG. 10 is a side view of the black key mass body drive unit.

First, the configuration of the electronic musical instrument shown mainly in FIG. 1 will be described. The electronic musical instrument 1 is an electronic keyboard instrument such as a desktop electronic organ, an electronic piano, or a synthesizer, and includes a keyboard device 2, an upper case 60, a lower case 70, an electronic circuit unit and a speaker (not shown). Yes.
The keyboard device 2 is provided with a large number of white keys 20 and black keys 40 attached to the key mounting portion 10K of the keyboard frame 10 as a key mounting member, and only the key main body portion to be pressed is exposed. The upper case 60 and the lower case 70 are housed in a case. The upper case 60 and the lower case 70 are fitted to each other, and are fastened together with the keyboard frame 10 that is a key support member by a set screw 71 and a plurality of set screws (not shown).
A mouth bar portion 64 is provided on the front surface of the upper case 60, and a music stand mounting groove 61 for inserting and mounting the music stand 62 is formed on the rear upper surface. Rubber feet 76 are attached to the four corners of the lower surface of the lower case 70.

Each of the white key 20 and the black key 40 constitutes a set of key units KU for each key range of one octave as shown in FIG. The key unit KU is composed of a first white key unit KUW1, a second white key unit KUW2, and a black key unit KUB.
The first white key unit KUW1 includes key body portions 23 of white keys 20 (C, E, G, and B keys shown in FIG. 2), which are four full-tone keys every other one octave from the outside. Each of the connecting portions 24 is connected to the key common holding portion 21 so as to be swingable in the direction of pressing and releasing keys.

In the second white key unit KUW2, each key body 23 of the white key 20 (D, F, and A keys shown in FIG. It is connected to the common holding part 22 so as to be swingable in the direction of pressing and releasing keys.
The black key unit KUB is a key body of each of the black keys 40 (C #, D #, F #, G #, A # keys indicated by solid lines in FIG. 2) which are five semitone keys indicated by virtual lines in FIG. Each of the portions 43 is connected to the key common holding portion 41 by a connecting portion 42 so as to be swingable in the key release / release direction.

In FIG. 5, reference numeral 23 denotes a key body portion of the white key 20, and 43 denotes a key body portion of the black key 40. The lengths of the key body portions 23 and 43 in the longitudinal direction are naturally white. The key body portion (hereinafter referred to as “white key body portion”) 23 of the key 20 is longer than the key body portion (hereinafter referred to as “black key body portion”) 43 of the black key 40.
Here, “white key” and “black key” do not necessarily mean “white key” and “black key”, but the upper surface of the key body is flat and long as described above. The key that is used to generate the whole sound when the key is pressed is the `` white key '', and the key that protrudes above the white key and has a shorter length. The keys are referred to as “black keys” for convenience. Therefore, even if the actual key is black and white, the key having the shape and function corresponding to the above-described white key is referred to as “white key”, and the key having the shape and function corresponding to the above-described black key is referred to as “black key”. Key.

  As shown in FIG. 6, the first white key unit KUW1, the second white key unit KUW2, and the black key unit KUB have their key common holding portions 21, 22, and 41 overlapped with each other to share a key. The holding part 30 is formed. The key common holding part 30 is formed on the rail-shaped fitting protrusion 21b formed on the key common holding part 21 of the first white key unit KUW1, and is formed on the second white key unit KUW2 key common holding part 22. The fitting concave groove 22a is positioned and fitted, and the fitting concave formed on the key common holding portion 41 of the black key unit KUB is formed on the rail-like fitting protrusion 22b formed on the key common holding portion 22. The groove 41a is positioned and fitted to be integrated.

  Further, the fitting groove 21a formed in the key common holding portion 21 of the first white key unit KUW1 is positioned and fitted to the rail-like fitting protrusion 15 formed in the key mounting portion 10K of the keyboard frame 10. 1 is inserted from above into the mounting holes 26, 26, 44 of the key common holding portions 21, 22, 41 forming the key common holding portion 30, and the key shown in FIG. Each key common holding part 21, 22, 41 is attached to the key attachment part 10K in common by being screwed into the key common holding part attachment screw hole 17 of the attachment part 10K.

  In this way, the first white key unit KUW1, the second white key unit KUW2, and the black key unit KUB are assembled on the keyboard frame 10 as a key unit KU for one octave as shown in FIG. By assembling the key units KU by connecting them in the key arrangement direction by the required key range, it is possible to configure a keyboard device having the required number of keys.

Here, details of the shapes of the connecting portions 24 of the first and second white key units KUW1 and KUW2 and the connecting portion 42 of the black key unit KUB will be described with reference to FIGS. 2 and 5 to 8. FIG.
As shown in FIGS. 2 and 8, the connecting portion 42 that connects each black key main body portion 43 of the black key unit KUB to the key common holding portion 41 so as to be swingable in the key-pressing direction is arranged as shown in FIGS. The overall width Wa in the direction is wider than the key width Wb of the black key body 40, and some of the portions Wc and Wd (see FIG. 8 for Wa, Wb, Wc, and Wd) overlap with the connecting portion 24 of the adjacent white key 20. The connecting portion 42 regulates the rocking in the key width direction when the black key 40 is pressed and released.

  As clearly shown in FIGS. 6 and 8, the connecting portion 42 of the black key 40 includes a thin-walled hinge portion 42b that enables the key to be pushed and released and a thick-walled connecting portion that is more rigid than the thin-walled hinge portion 42b. 42a, and the thick connecting portion 42a protrudes from both side surfaces of the rear end portion 43e (FIG. 8) of the black key main body portion 43 in the adjacent key direction, and extends rearwardly. It is connected to the portion 42b and is further coupled to the key common holding portion 41 through the thin hinge portion 42b. The thin hinge portion 42b has an opening 47 in the middle in the key width direction as clearly shown in FIGS. 2 and 8, and is thus divided into left and right portions.

By forming the thin hinge portion 42b in this way, while increasing the flexibility in the key pressing direction, the cross-section secondary moment with respect to the force in the key width direction (lateral direction) is increased together with the thick connection portion 42a, and the key Even if the guide is not used, the lateral movement (yawing) of the black key body 43 in the key width direction can be sufficiently regulated.
The protruding amount of the thick connecting portion 42a from the both side surfaces of the rear end portion 43e of the black key main body 43 in the connecting portion 42 is different for each black key 40 as shown in FIG. The width is not necessarily different for each key. In any case, on the average, the wide portion as the black key connecting portion can have a width of 12/5 = 2.4 keys per key. Widely, the effect of restricting the lateral movement of the black key body 43 in the key width direction is enhanced.

  On the other hand, each connecting portion 24 for connecting the white key main body portion 23 of the first and second white key units KUW1 and KUW2 to the key common holding portion 21 or 22 so as to be swingable in the key pressing direction is shown in FIGS. 7, the full width We in the key arrangement direction is narrower than the full width Wa in the key arrangement direction of the connecting portion 42 of the black key unit KUB described above, and is almost equal to the width of the rear end portion of the white key main body 23. The width is formed.

  As shown in FIG. 6, each connecting portion 24 includes a thin horizontal hinge portion 24 a extending in the key width direction and a vertical hinge portion 24 b extending in the thickness direction along the longitudinal direction of the key. As clearly shown in FIG. 5, 24 b is formed in a letter “e” shape when viewed from above. The front end portion of the thin horizontal hinge portion 24a is integrally connected to the rear end 43e of the white key body portion 23, and the rear end portion of the vertical hinge portion 24b is integrally connected to the key common holding portion 21 or 22. .

The horizontal hinge portion 24a supports the white key main body portion 23 so as to be swingable in the key pressing direction, and the vertical hinge portion 24b supports the white key main body portion 23 so as to be swingable in the key width direction. Therefore, the vertical hinge portion 24b in the connecting portion 24 corresponds to the key width direction swing allowing portion.
Then, the positioning of the front end portion of the white key main body portion 23 in the key arrangement direction and the regulation of the rolling are performed by a guide portion described later provided on the free end side of the white key 20.

The reason for the presence of the vertical hinge portion 24b is that the keyboard frame 10 and the key unit KU are made of resin, so that the key guide portion 12 and / or the cover to be described later may be affected by shrinkage errors during molding and variations in each portion during thermal cooling. This is to prevent stress from being generated at the key free end when the key is pressed or released even if the position accuracy of the guide portion 33 may slightly vary.
As described above, the connecting portion 42 of the black key 40 has a full width in the key width direction that is wider than the key width at the rear end of the black key main body 43, and as shown in FIGS. The overlapping portion overlaps with the connecting portion 24 of the adjacent white key 20.

Further, as a part of the overlapping portion in the connecting portion 42, the portions protruding from both side surfaces of the rear end portion 43e of the black key main body portion 43 of the thick connection portion 42a in the adjacent key direction are adjacent white portions. The key 20 overlaps the upper surface of the rear end of the key body 23 of the key 20.
Further, as shown in FIGS. 6 and 7, a relief portion 25 in which the height of the upper surface 23 a of the rear end portion of the white key main body portion 23 is set lower than the other portions is used as the rear end portion of the white key main body portion 23. Is formed.
When the keyboard device is configured by superimposing the black key unit KUB on the first and second white key units KUW1 and KUW2, the connecting portion 42 of the black key 40 is connected to the escape portion 25 of the white key main body portion 23. The thick connection part 42a which is a part fits and overlaps. In this embodiment, the upper surface 23a of the white key body 23 and the upper surface of the thick connection portion 42a of the connecting portion 42 of the black key 40 are thereby flush with each other.

With this configuration, in the keyboard device that does not need to provide a guide portion for at least the black key 40, the hinge mechanism by the connecting portions 24 and 42 of the white key 20 and the black key 40 are all white key main body 23. Therefore, the degree of freedom in mounting design (panel layout etc.) near the fulcrum of the key is improved while the height is held down. Furthermore, since the rotation fulcrum of the black key 40 and the white key 20 approaches in the vertical direction, a keyboard device that is easier to play is realized in terms of key operability. In particular, the scaling performance (for example, C, C ^# , D, D ^# , E, F,... By keys) is easy to operate.

In addition, the thickness of the white key main body 23 can be increased while suppressing the height of the keyboard device, and the white key main body 23 can be prevented from being bent when the key is depressed. Furthermore, by making the white key main body 23 longer, it becomes close to a parallel key press, so that it is easy to play.
On the other hand, the black key 40 can also have a sufficient thickness without increasing the thickness of the thick connecting portion 42a of the connecting portion 42. Therefore, it is possible to increase the rigidity against the lateral deflection in the key width direction.

The gripping unit PU shown in FIG. 2 and the like grips a three-tier key unit KU composed of the first white key unit KUW1, the second white key unit KUW2, and the black key unit KUB when attached to the keyboard frame 10. It is a gripping part. At that time, the mass body driving portions 29 and 45 are fitted to the main driven portions 53W and 53B and the sub driven portions 54W and 54B of the mass bodies 50W and 50B, and the mating ridge portions 15 on the keyboard frame 10 side are fitted. The key common holding unit 30 on the key side is mounted.
This gripping portion PU has an opening 47 formed between the two thin hinge portions 42b and 42b constituting the connecting portion 42 of the black key unit KUB from the key common holding portion 21 of the first white key unit KUW1 in the lowermost layer. It is provided as a gripping part composed of a horizontal part PUa and a vertical part PUb protruding so as to pass through (see FIG. 8) (see FIG. 7).

  When the key unit KU is assembled to the mass bodies 50W and 50B and the keyboard frame 10, when the entire key unit KU is lifted by the gripping part PU, the key units KUW1, KUW2, and KUB are temporarily held so that they do not come apart. The fitting means to be provided is provided at an intermediate portion in the width direction of the key common holding portions 21, 22, 41, which is the base end portion of each key unit, for example, at a substantially central portion. Specifically, as shown in FIG. 5, the fitting means includes a fitting hole ho1 provided in the key common holding portion 22 of the twenty-first white key unit KUW2, and a black key corresponding to the fitting hole ho1. A protrusion (not shown) provided to protrude downward from the lower surface of the key common holding portion 41 of the unit KUB, a protrusion Pj provided to protrude downward from the lower surface of the key common holding portion 22 of the second white key unit KUW2, and the protrusion It consists of a fitting hole ho2 provided on the upper surface of the key common holding part 21 which is the lowest part of the first white key unit KUW1 provided corresponding to Pj.

  When the key unit KU is temporarily arranged on the keyboard frame 10, the fitting means as temporary holding means for keeping the position from shifting is the first white key unit KUW1 in the lowermost layer. It is provided on the lower surface of the key common holding portion 21 and the fitting protrusion 15 of the keyboard frame 10 (not shown). For example, the fitting means is configured by a protrusion protruding downward from the lower surface of the key common holding portion 21 and a hole provided in the fitting protrusion 15.

  Since it is configured as described above, it is not limited to the above-described assembly of the key unit KU to the keyboard frame 10 just by gripping the grip portion PU provided in the first white key unit KUW1 in the lowermost layer. The key unit KU can be easily detached from the keyboard frame 10 during maintenance and inspection. If all the hinges of each key of the three-tier key unit are widened as in the prior art, they would not be provided by interference when the grip portion was provided, but the keyboard unit according to the present invention devised the grip portion as described above. Is provided.

Here, returning to FIG. 1, the configuration of the keyboard frame 10 which is a key attachment member and its related parts will be described.
The keyboard frame 10 includes a front lower portion located on the lower left side in FIG. 1, a rear lower portion located on the lower right side, an upper portion located on the upper side, and a rib portion that reinforces and connects them. Are integrally formed of resin.

  And in the front lower part, the guide support part 11 which formed the white key guide 12 integrally, the white key lower limit stopper holding part 10F, the key unit slide surface 19, the mass body attaching part 10G, and the lower case fixing Boss portions 10e to 10g are formed. A mass lower limit stopper holding portion 10L, a lower case fixing boss portion 10h, and the like are formed in the rear lower portion. Furthermore, a key attachment portion 10K, a switch board attachment portion 10S, a mass body upper limit stopper holding portion 10H, an upper component attachment portion 10J, and the like are formed in the upper portion.

  The key unit slide surface 19 is used when the above-described key unit KU is mounted on the keyboard frame 10. That is, when the key unit KU is inserted from the front side of the keyboard frame 10 through the gap between the guide support portion 11 and the switch substrate 80, the mass body drive portions described later provided in the white keys 20 and the black keys 40, respectively. The lower end surfaces 29a, 45a of the 29, 45 are slid while contacting the inclined surface of the key unit slide surface 19, and main driven portions 53W, 53B of a white key mass body 50W and a black key mass body 50B described later are provided. And the sub driven parts 54W and 54B, the fitting parts 291 and 451 of the mass body driving parts 29 and 45 can be automatically fitted.

Therefore, the upper and lower surfaces of the fitting parts 291 and 451 are fitted between the main driven parts 53W and 53B and the sub driven parts 54W and 54B. Power is transmitted between them.
Components such as an operation panel substrate housed in the upper part of the upper case 60 can be attached to the upper component attaching portion 10J.

  The rib portion includes a white key lower limit stopper holding portion 10F and a lower rib 10a of the key unit slide surface 19, an upper rib 10b of the boss portion 10f, an inner rib 10c of the mass body mounting portion 10G, and a lower front portion. It consists of a main rib 10d that connects the rear lower part and the upper part. As shown in FIG. 2, the rib portions formed by these ribs are provided at a plurality (about two places per octave) at intervals in the key arrangement direction along the key longitudinal direction.

  On the upper surface of the white key lower limit stopper holding portion 10F, a white key lower limit stopper 34 made of a belt-like felt material extending in the key arranging direction is adhered and held. On the upper surface of the mass body lower limit stopper holding portion 10L, as shown in FIGS. 2 and 9, the mass body lower limit made of a belt-like felt material extending in the direction in which mass bodies (hammers) 50W and 50B described later are arranged. A stopper 84 is stuck and held. Further, as shown in FIG. 7, a mass body upper limit stopper 83 made of a strip-like felt material extending in the direction in which the mass bodies 50W and 50B are arranged is adhered and held on the lower surface of the mass body upper limit stopper holding portion 10H. Yes.

Here, the guide part of the white key will be described with reference to FIGS.
A plate-shaped guide support portion 11 is disposed at a position corresponding to the vicinity of the free end of each white key at the upper part on the front end side of the keyboard frame 10, as shown in FIG. 2 and FIG. Are arranged in line. A plate-shaped white key guide 12 is vertically formed so as to protrude forward from the front surface of each guide support portion 11. The guide support part 11 and the white key guide 12 are T-shaped guide members as shown by broken lines in FIG. 2 and phantom lines in FIG. 4 when viewed from above or below.

  On the other hand, on the free end side of each white key 20, as shown in a bottom view of FIG. A front end wall 31 is provided, and the upper surface portion slightly protrudes forward. An inner front end wall 32 is formed on the inner side of the outer front end wall 31 over the entire height region of the front end portion 20 a of the white key main body portion 23. A slit 33a is formed from the lower end along the key height direction at the intermediate portion in the key width direction of the inner front end wall 32, and a pair of guided portions 33 that protrude symmetrically forward from each other are formed. Yes. The gap width of the slit 33 a of the guided portion 33 is slightly larger than the thickness of the white key guide 12.

  When the above-described key unit KU is attached to the keyboard frame 10, as shown in FIGS. 2 to 4, each white key guide 12 is inserted into the slit 33a of the guided portion 33 of each white key 20. Then, the positioning of the tip of each white key 20 is positioned and the lateral vibration during key depression is regulated. Note that. Since each white key main body 23 can swing in the key width direction by the action of the vertical hinge portion 24b of the connecting portion 24 described above, even if there is a slight manufacturing error or assembly error, each white key main body portion 23 can be comfortably provided. The arrangement positions of the keys can be aligned, and the key pressing operation can be performed smoothly. Lubricating grease may be applied to the respective white key guides 12 and the guided portions 33 of the respective white keys 20.

  Returning to FIG. 1 again, a switch board 80 is fixedly attached to the switch board attachment portion 10S of the keyboard frame 10 by a switch board engaging rod 35. A large number of key switches 81 are arranged in rows as shown by broken lines in FIG. 2 at positions corresponding to intermediate portions in the longitudinal direction of the keys 20 and the black keys 40.

  Each of the key switches 81 has a dome-shaped movable portion made of synthetic rubber, a pair of pressed portions (indicated by two small circular broken lines in FIG. 2) on the movable portion, and a conductive material on the inside thereof. A pair of movable contacts made of a synthetic rubber is provided, and each movable contact is opposed to two sets of fixed contacts formed on the switch substrate 80 to form a two-contact (two-make) key switch. When the white key 20 or the black key 40 is depressed, the movable portion is pressed on the lower surface thereof, and the pair of movable contacts sequentially come into contact with the two sets of fixed contacts to turn on the respective contacts. Is output. Further, the key pressing speed can be detected by the time difference between the timings when the respective contacts are turned on, and the musical sound generated according to the detected key pressing speed can be controlled.

Next, the keyboard device 2 is provided with a mass body (generally called a hammer) that interlocks with each key so that a heavy touch feeling can be obtained when each key is pressed. Will be described with reference to FIGS. 2, 9, and 10 in addition to FIG.
The white key mass body 50W for each white key 20 and the black key mass body 50B for each black key 40 are respectively attached to the mass body mounting portion 10G of the keyboard frame 10 in the direction indicated by the arrow M in FIG. Is attached to be swingable.

  The white key mass body 50W and the black key mass body 50B have almost the same configuration, and the swing supported portion 51W or 51B, the main driven portion 53W or 53B, and the sub driven portion 54W or 54B are made of resin. Are integrally formed to form a driving force transmission portion. Then, the front end portion of the inertia moment generating portion 52W or 52B made of a rod-like metal material such as iron is integrated with the swing supported portion 51W or 51B by outsert molding.

  The rear end portions of the inertia moment generating portions 52W and 52B are bent upward at a substantially right angle by bending, respectively, and further bent at a substantially right angle so as to return to the front, and the inertia moment generating portion of the black key mass body 50B. The rear end portion of 52B forms a U-shaped mass concentration portion 52Bc. The rear end portion of the inertia moment generating portion 52W of the white key mass body 50W is further bent downward at a substantially right angle to form a substantially rectangular loop-shaped mass concentrating portion 52Wc.

  The mass concentrating parts 52Wc and 52Bc protrude outward (rear) in the longitudinal direction of the key from the mass upper limit stopper holding part 10H of the keyboard frame 10, and the inertia moment generating parts 52W and 52B are respectively the mass upper limit stoppers. The upper surface of the white key 20 is substantially flush with the upper surface of the key main body 43 of the white key 20 or the upper surface of the thick-walled connecting portion 42a of the black key 40. The portions in front of the mass concentrating portions 52Wc and 52Bc in the inertia moment generating portions 52W and 52B serve as connecting portions that connect the mass concentrating portions 52Wc and 52Bc to the driving force transmitting portion described above.

  The rocking supported portions 51W and 51B of the mass bodies 50W and 50B are provided with bearing portions 13W and 13B, respectively, in which concave portions are formed in the radial direction and guide tongues Q are projected rearward from the lower side of the concave portions. It has been. On the other hand, a pair of support ribs 10W and 10B facing each other at a predetermined interval in the key width direction are integrally formed on the upper surface of the mass body mounting portion 10G of the keyboard frame 10 as shown in FIG. Rotating shafts 14W and 14B are provided so as to bridge between the pair of support ribs. As shown in FIG. 2, the mass body attaching portion 10G is formed with openings 38 and 48 through which the molds enter when the rotating shafts 14W and 14B are formed. In FIG. 1, the support ribs on the near side of the pair of support ribs 10W are removed.

Then, the rotating shafts 14W and 14B are fitted into the recesses of the bearing portions 13W and 13B of the mass bodies 50W and 50B, so that the white key mass body 50W is moved to the bearing portion 13W, the rotating shaft 14W, and the pair of support ribs 10W. The black key mass body 50B is pivotally supported by the mass body mounting portion 10G via the bearing portion 13B, the rotating shaft 14B, and the pair of support ribs 10B.
As shown in FIGS. 2 and 9, the pivot position, that is, the position in the key longitudinal direction of the rotation shafts 14W and 14B is deviated, and the rotation shaft 14W with respect to the white key mass body 50W is the black key mass. It is closer to the front end than the pivot shaft 14B with respect to the body 50B.

  Further, as shown in FIG. 1, a main driven portion 53W and a sub driven portion 54W are provided at the front end portion of each white key mass body 50W with a swing supported portion 51W spaced apart in the vertical direction. The main driven portion 53W protrudes more forward than the sub driven portion 54W. On the other hand, a mass body drive unit 29 projects straightly downward as shown in FIG. 1 on the lower surface of the white key 20 near the rear end of the wide portion shown in FIG. The lower end surface of the mass body drive unit 29 comes into contact with the upper surface of the main driven portion 53W of the corresponding white key mass body 50W. Further, the lower portion of the mass body driving portion 29 is formed in a cavity having an open rear surface, and the front end portion of the sub driven portion 54W loosely enters there as shown by a broken line in FIG.

With this configuration, when the white key 20 is depressed, the mass body drive unit 29 is lowered to drive the main driven portion 53W, and the white key mass body 50W is used with the rotation shaft 14W as a fulcrum. In FIG. 1, the portion C of the inertia moment generating portion 52 </ b> W is rotated to the position indicated by the imaginary line in contact with the mass body upper limit stopper 83, so that a heavy touch feeling is given. When the key is released, the inner wall of the lower end of the mass body driving portion 29 engages with the sub driven portion 54W and raises it, so that the white key mass body 50W rotates clockwise in FIG. 1 with the rotating shaft 14W as a fulcrum. The mass concentration portion 52Wc quickly returns to the position indicated by the solid line in contact with the mass body lower limit stopper 84.
In this manner, the mass body drive unit 29 is moved to the main driven portion 53W and the sub driven portion 54W of the white key mass body 50W so that the white key 20 and the white key mass body 50W always rotate in conjunction with each other. It is made to engage with.

  Similarly, at the front end portion of each black key mass body 50B, a main driven portion 53B and a sub driven portion 54B indicated by phantom lines in FIG. 9), the main driven portion 53B protrudes more forward than the sub driven portion 54B. On the other hand, as shown in FIG. 10, each black key 40 has a mass body drive unit 45 projecting from the lower surface of the front end portion thereof. The mass body driving portion 45 extends in a crank shape downward, forward, and downward, and has a lower end surface 45a abutting against the upper surface of the main driven portion 53B of the corresponding black key mass body 50B. As indicated by phantom lines in FIG. 9, the direction position is aligned with the contact position between the lower end surface of the white key mass body drive unit 29 and the main driven portion 53W of the white key mass body 50W. .

The lower end portion 45a of the mass body driving unit 45 is also formed in a cavity having an open rear surface, and the front end portion of the sub driven portion 54B enters into the space as shown by phantom lines in FIG.
As a result, as in the case of the white key 20 and the white key mass body 50W described above, the black key 40 and the black key mass body 50B always rotate in conjunction with each other.

In this embodiment, as described above, the mass body drive unit 45 is extended to the near side below the white key 20, and the white key mass body by the mass body drive units 29, 45 of the white key 20 and the black key 40. The drive positions in the key longitudinal direction of 50W and the black key mass body 50B are aligned at substantially the same position. On the other hand, the positions of the rotation shafts 14W and 14B, which are the rotation fulcrums of the white key mass body 50W and the black key mass body 50B, are different (in a staggered arrangement).
As a result, the distance from the point at which the white key mass body 50W and the black key mass body 50B are driven by the mass body drive units 29 and 45 to the rotation fulcrum is longer for the black key than for the white key. Thus, the distance from the pivot point of the inertial moment generating part 52B of the black key mass body 50B to the portion C contacting the mass body upper limit stopper 83 is the pivotal support point of the inertial moment generating part 52W of the white key mass body 50W. From the distance C to the portion C that contacts the mass body upper limit stopper 83, so that it is possible to balance the pressing feeling of the white key 20 and the black key 40.

  Here, in the white key mass body 50W and the black key mass body 50B in this embodiment, the mass concentration portions 52Wc and 52Bc are also in the key longitudinal direction as compared with the mass body upper limit stopper holding portion 10H of the keyboard frame 10 as described above. And the moment of inertia generating portions 52W and 52B are in the highest positions where they abut against the mass upper limit stopper 83, and the upper surface thereof is the upper surface of the key body 43 of the white key 20 or the black key. The reason why the upper surface of the 40 thick connection portions 42a is substantially flush with the upper surface will be described.

  In a piano keyboard device with a mass body (hammer), it is important to balance the mounting space in order to realize a touch feeling of key pressing. In particular, the lower the price range, the greater the dimensional constraints of the instrument body and the greater the possibility that it will have to sacrifice the performance of the keyboard, so it is necessary to maximize the space efficiency among them. Become. By arranging the members that cannot be omitted at the minimum and other functional parts at the same height, it is possible to eliminate a useless space. It is particularly important that the unit height is almost determined by the amount of movement of the mass body (hammer).

Therefore, by removing the mass concentrated portion of the mass body outside the mass body upper limit stopper holding portion of the keyboard frame in the key longitudinal direction, it is possible to improve the equivalent mass of the mass body, reduce the weight, and thereby reduce the cost. It becomes possible to plan at the same time.
The mass feeling is proportional to the square of the distance from the rotation fulcrum of the mass body to the center of gravity, so it is desirable that the mass concentrating portion be as far as possible from the rotation fulcrum. For this reason, the mass concentration part is moved out of the keyboard frame, and when it is turned upward, the upper end of the mass concentration part is at the same height as the highest point of the keyboard frame or key. It is possible to achieve both improvement and securing of mounting flexibility at a high level.

  Further, in this embodiment, the mass concentrating portions 52Wc and 52Bc of the mass bodies 50W and 50B are formed by bending the rear end portion of the rod-shaped metal member upward in the key pressing / releasing key direction and further bending the connecting member side. As a result, the equivalent weight can be increased without increasing the total length of the mass bodies 50W and 50B, thereby increasing the moment of inertia and enhancing the touch feeling. In addition, since the mass concentrating portions 52Wc and 52Bc are bent in a space parallel to the pressing / releasing key direction with the same width as the diameter of the rod-shaped metal member, the upper space is avoided to avoid interference with the mass body of the adjacent key. Can be used effectively.

The bent shape of the mass concentrating portions 52Wc and 52Bc is not limited to a U shape or a square shape, but may be various shapes such as a U shape, a triangle, a circle, and a spiral shape.
Further, in this embodiment, the effective lengths (length when extended = weight) of the mass concentrating portions 52Wc and 52Bc of the white key mass body 50W and the black key mass body 50B are made different from each other. The touch feeling of 20 and the black key 40 is made uniform.

  In the keyboard device 2 of this embodiment, as described with reference to FIG. 1, each part of the keyboard frame 10 is integrally formed by being supported by many ribs. Then, at least a part of the lower edge of the largest rib 10d among the ribs (in the example of FIG. 1, an intermediate portion along the key longitudinal direction) is in the lowest lowered state indicated by the solid lines of the mass bodies 50W and 50B. Sometimes formed along the lower edge. By doing in this way, the space made in the lower part of the keyboard frame 10 can be used effectively. For example, functional components that are long in the key and mass body arrangement direction (key width direction) can be easily arranged.

  In this case, a rotation fulcrum portion formed by the bearing portions 13W and 13B of the mass bodies 50W and 50B and the rotation shafts 14W and 14B on the mass body attachment portion 10G side is set to a predetermined position from the lowermost end of the keyboard frame 10 as a key attachment member. A space outside the moving range is formed below the mass bodies 50W and 50B at a height position, and the uppermost portion of the space is configured to coincide with a part of the lower edge of the rib 10d. . Furthermore, a concave portion that enters the space can be formed in the lower case 70 attached to the lower end of the keyboard frame 10, and the concave portion can be used as a functional member accommodating portion. In the example shown in FIG. 1, one of the recessed portions is a battery chamber 18 that houses a battery or a battery pack, and a lid 75 is detachably provided.

In this way, in the case of a portable electronic keyboard instrument, a necessary battery or a battery pack incorporating the battery is not provided with an extra space (without increasing the height of the keyboard device). ) Can be stored.
The other recessed portion is a functional component storage portion 16 that can store various functional components that are long in the key arrangement direction. A temporary holding member for fitting the keyboard frame 10 to the lower case 70 can be fitted into the functional component storage unit 16, and accessories such as a cord and a microphone can be stored.

The lower case 70 is screwed to the boss portions 10f, 10g, 10h of the keyboard frame 10 by set screws 72, 73, 74.
It is also possible to integrate the keyboard frame 10 and the lower case 70 so that the key unit and the mass body are supported by a part of the lower case.

Further, the lowermost end of the keyboard frame 10 which is a key attachment member is provided in a distributed manner only at two or three places on the lower surface of the keyboard frame 10. In the example shown in FIG. 1, only the lower surfaces of the boss portions 10f and 10h are the lowermost end of the keyboard frame 10, and the other portions are higher than the lowermost end. For example, the lower surface of the boss portion 10g is slightly higher than the lower surface of the boss portion 10f. When the lowest end is two places, at least one needs to have a certain length.
In this way, when the keyboard device 2 is directly placed on the shelf of the keyboard instrument without attaching the lower case 70, the keyboard device 2 can be stably placed without rattling.

  The present invention can be applied not only to a keyboard instrument having a mass body but also to a keyboard instrument not having a mass body, and not only to an electronic keyboard instrument but also to an electric keyboard instrument using a natural sounding body and other keyboard instruments. Applicable. Needless to say, the shape and arrangement of each part are not limited to those of the embodiments, and can be appropriately changed according to the specifications of the applied instrument.

  The keyboard device according to the present invention can be applied to various keyboard instruments such as an electronic keyboard instrument such as an electronic organ, an electronic piano, and a synthesizer, or an electric keyboard instrument. In particular, it is suitable for application to a small electronic keyboard instrument having a mass body (hammer) for each key, has a good key touch feeling, and can provide a high-performance and compact electronic keyboard instrument at low cost. .

It is a schematic sectional drawing in alignment with the key longitudinal direction of the electronic musical instrument provided with the keyboard apparatus which is one Example of this invention. It is a top view of the key range part of 1 octave of the keyboard apparatus. It is the same front view. It is a bottom view of the free end side of the white key. It is a top view of only the key unit which shows the white key unit with a solid line, and shows a black key unit with a virtual line.

It is a side view which expands and shows the key common holding | maintenance part vicinity of the key unit. It is a perspective view which shows the key attachment part vicinity of the keyboard frame, and a part of 1st white key unit attached there. It is the perspective view which looked at a part of black key unit from the lower part. FIG. 3 is a plan view showing the keyboard device shown in FIG. 2 with a key unit and a switch board removed and a part thereof broken away. It is a side view of the mass body drive part of a black key.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electronic musical instrument, 2 ... Keyboard apparatus, 10 ... Keyboard frame (key attachment member), 10W, 10B ... Pair support rib, 10F ... White key lower limit stopper holding part, 10G ... Mass body attachment part, 10K ... Key attachment , 10H: Mass body upper limit stopper holding portion, 10L: Mass body lower limit stopper holding portion, 10J: Upper part mounting portion, 10S: Switch board mounting portion, 10a-10d ... Rib, 10e-10h ... Boss portion, 11 ... Guide Support part, 12 ... White key guide (guide part), 13W ... Bearing part of white key mass body, 13B ... Bearing part of black key mass body, 14W ... Rotating shaft of white key mass body, 14B ... Black Rotating shaft of key mass body, 15 ... fitting protrusion, 16 ... functional part storage, 17 ... key common holding part mounting screw hole, 18 ... battery chamber, 19 ... key unit slide surface,

DESCRIPTION OF SYMBOLS 20 ... White key, 20a ... White key tip part, 21 ... White key key common holding part (bottom), 21a ... Fitting groove part, 21b ... Fitting protrusion, 22 ... White key key common holding part (Top), 22a ... concave groove portion for fitting, 22b ... protruding ridge portion, 23 ... white key main body portion, 23a ... upper surface of white key main body portion, 24 ... white key connecting portion, 24a ... horizontal hinge portion, 24b DESCRIPTION OF SYMBOLS ... Vertical hinge part, 25 ... Relief part, 26 ... Mounting hole, 29 ... White key mass body drive part, 30 ... Key common holding part (whole), 31 ... Outer front end wall of white key, 32 ... Inside of white key Front end wall 33 ... White key guided portion, 33a ... Slit, 34 ... White key lower limit stopper, 35 ... Switch board locking rod, 36, 37 ... Case coupling through hole, 38 ... White key mass body Bearing fitting hole,

40 ... Black key, 41 ... Black key common holding portion, 41a ... Fitting groove portion, 42 ... Black key connecting portion, 42a ... Thick connection portion, 42b ... Thin hinge portion, 43 ... Black key body portion 43e ... rear end of the black key body, 44 ... mounting hole, 45 ... black key mass drive unit, 46 ... case coupling through hole, 47 ... opening, 48 ... black key mass bearing fitting Hole, 50W ... Mass body for white key (hammer), 50B ... Mass body for black key (hammer), 51W, 51B ... Swing supported part of mass body, 52W, 52B ... Inertia moment generating part of mass body, 52Wc , 52Bc ... mass concentrating part of weight part, 53W, 53B ... main driven part of mass body, 54W, 54B ... sub driven part of mass body,

60 ... Upper case, 61 ... Music stand mounting groove, 62 ... Music stand, 64 ... Upper case mouth bar portion, 70 ... Lower case, 71-74 ... Set screw, 75 ... Battery compartment cover, 76 ... Rubber feet, 80 ... Switch board, 81 ... Key switch (with rubber movable part), 82 ... Key unit assembly screw,
83 ... Mass body upper limit stopper, 84 ... Mass body lower limit stopper KU ... Key unit, KUW1 ... First white key unit (C, E, G, B key),
KUW2 ... second white key unit (D, F, A key), KUB ... black key unit,

Claims (5)

A keyboard device in which a plurality of keys are provided in the key attachment portion of the key attachment member,
Each of the plurality of keys includes a key body portion that is operated to be depressed, a key common holding portion that holds the key body portions in a swingable manner with respect to the key attachment portion, and the key body portions. In a keyboard device comprising a key unit having a connecting part for holding the key common holding part so as to be swingable in the pressing / releasing key direction,
The key unit is divided into a white key unit in which each key is a white key and a black key unit in which each key is a black key,
The length of the key body in the longitudinal direction is such that the white key is longer than the black key,
The black key unit is configured such that the entire width in the key arrangement direction of the connecting portion is wider than the key width of the key body portion of the black key, and the key width direction when the black key is pressed and released by the connecting portion. To regulate the swing of the
The white key unit is configured such that the full width of the connecting portion in the key arranging direction is narrower than the full width of the connecting portion of the black key unit in the key arranging direction, and the white key unit swings in the key arranging direction on the free end side of the white key. A keyboard device characterized in that a guide portion is provided for restricting the movement and guiding the pressing and releasing key movement. A keyboard device in which a plurality of keys are provided in the key attachment portion of the key attachment member,
Each of the plurality of keys includes a key body portion that is operated to be depressed, a key common holding portion that holds the key body portions in a swingable manner with respect to the key attachment portion, and the key body portions. In a keyboard device comprising a key unit having a connecting part for holding the key common holding part so as to be swingable in the pressing / releasing key direction,
The key unit is divided into a white key unit in which each key is a white key and a black key unit in which each key is a black key,
The length of the key body in the longitudinal direction is such that the white key is longer than the black key,
The black key unit is configured such that the entire width in the key arrangement direction of the connecting portion is wider than the key width of the key body portion of the black key, and the key width direction when the black key is pressed and released by the connecting portion. To regulate the swing of the
In the white key unit, the connecting portion has a key width direction swing allowing portion, and a guide portion for restricting the swing in the key arrangement direction to guide the pushing and releasing key movement to the free end side of the white key. A keyboard device characterized by being provided. The keyboard device according to claim 1 or 2,
The connecting portion of the black key unit has an overlapping portion that partially overlaps the connecting portion of the white key that is adjacent to the connecting portion.
The overlapping part of the black key connecting part is configured to overlap the upper surface of the rear end part of the key body part of the white key, and the height of the upper surface of the rear end part is the other part of the key body part. A relief portion set lower than the white key is formed at a rear end portion of the key body portion, and the keyboard device is configured by superimposing the black key on the white key. A keyboard device characterized in that a part of the connecting part of the black key is fitted to the part. The keyboard device according to any one of claims 1 to 3,
The connecting portion of the black key is composed of a thin-walled hinge portion that enables rotation of the push-and-release key and a thick-walled connecting portion that is stiffer than the thin-walled hinge portion, and the thick-walled connecting portion is a key body portion of the black key. A keyboard device, wherein the keyboard device is configured to extend rearward from a rear end portion, to be connected to the thin hinge portion, and to be coupled to the key common holding portion via the thin hinge portion. The keyboard device according to any one of claims 1 to 4,
A keyboard device comprising: a mass body that is driven by a drive unit provided below each of the plurality of keys; and a mass body attaching portion that attaches each mass body.

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