JP4549090B2 - Rotating parts of keyboard instruments and key support mechanism - Google Patents

Description

  The present invention relates to a support mechanism for a rotating component of a keyboard instrument that supports a rotating component that rotates with key depression, and a support mechanism for a key of a keyboard instrument that supports a key.

  In general, in an acoustic piano, many rotating parts that rotate when a key is pressed, such as a whippen, a jack, and a hammer, are used. A center pin and a bushing cloth are used to rotatably support these rotating parts. Specifically, the pivot pin is pivotally engaged with the cylindrical bushing cloth attached to the pin hole of the support component, so that the pivot component pivots on the support component. It is supported freely. This bushing cloth is composed of wool fibers woven in a felt shape.

  However, in the above acoustic piano, the bushing cloth is made of wool fiber. When the humidity is high, the bushing cloth expands due to moisture absorption, so that the clearance between the bushing cloth inner diameter and the center pin is reduced. Becomes difficult to rotate. In extreme cases, noise is generated when the rotating component rotates. On the other hand, when the humidity is low, the bushing cloth contracts due to moisture release, thereby increasing the clearance with the center pin. As a result, shaft rotation of the rotating component occurs, and the rotation becomes unstable. As described above, a stable rotating operation of the rotating component cannot be obtained due to the influence of dry and wet, and the touch weight of the key becomes unstable.

  In order to avoid such problems, for example, Patent Document 1 discloses that a bushing cloth is immersed in water containing a surfactant and then dried in a state where a center pin is fitted to the bushing cloth. Has been. However, even if such a treatment is applied to the bushing cloth, fluctuations in the clearance with the center pin due to the influence of dry and wet cannot be sufficiently suppressed, and thus the above-described problems may not be sufficiently solved. Further, since the processing as described above is required, the manufacturing cost of the keyboard instrument increases accordingly.

  For this reason, it is known to use a bearing made of a fluororesin instead of the bushing cloth. However, in general, fluororesin is vulnerable to impact, so if the impact is applied to the bearing during key pressing during performance, transporting or adjusting the piano, the bearing will be damaged and the rotating parts will move. There is a risk of disappearing. Moreover, since the cost of fluororesin is high, the manufacturing cost of a keyboard instrument will be increased.

  In general, the bushing cloth as described above is also used for a key. Specifically, a balance pin hole is formed at the center of the key, and the key is rotatably supported in a state where the balance pin hole is engaged with the balance pin. In addition, two sheet-like bushing cloths are affixed to the inner surface of the balance pin hole so as to face each other, and these bushing cloths slide along the balance pins when the key is rotated. To do. Furthermore, a front pin hole is formed in the front part of the lower surface of the key, and a bushing cloth is affixed to the inner side surface of the key, while the bushing cloth slides along the front pin when the key rotates. The key rotation is guided. For this reason, the bushing cloth expands and contracts due to moisture, and the clearance with the balance pin and the front pin fluctuates. As a result, the key does not rotate stably, and the key touch weight also becomes unstable. The same problem as parts occurs.

  The present invention has been made in order to solve the above-described problems, has high impact resistance, can ensure a stable rotating operation of rotating parts regardless of dryness and humidity, and reduce manufacturing costs. It is a first object of the present invention to provide a support mechanism for a rotating part of a keyboard instrument. It is a second object of the present invention to provide a key support mechanism for a keyboard instrument that has high impact resistance, can ensure a stable rotation of the key regardless of dryness and can reduce manufacturing costs. To do.

Japanese Patent Laid-Open No. 8-240174

  In order to achieve the first object, the invention according to claim 1 is a support mechanism for a rotating component of a keyboard instrument that supports a rotating component that rotates when a key is pressed, and supports the rotating component. A pin hole is formed in one of the support component, the rotation component, and the support component, and is formed of a thermoplastic elastomer and fixed to the pin hole. And a pin that is provided on the other of the support parts and that is rotatably engaged with the bearing.

  According to the support mechanism of the rotating component of the keyboard instrument, when the key is depressed, the rotating component is rotated via the pin and the cylindrical bearing fixed to the pin hole and engaged with the pin. Move. This bearing is made of a thermoplastic elastomer. Unlike natural fibers, thermoplastic elastomers hardly expand or absorb shrinkage due to moisture absorption. For this reason, the clearance between the pin and the bearing is maintained almost constant regardless of changes in humidity. Can be secured. Accordingly, the touch weight of the key can be stabilized. This eliminates the need for a treatment that is conventionally performed to remove the effects of dryness and humidity, after immersing the bushing cloth in water containing a surfactant, and then reduces the manufacturing cost. it can.

  The thermoplastic elastomer is rubbery and elastic at room temperature. Therefore, even if an impact is applied to the bearing when playing a key or when carrying or adjusting a keyboard instrument, the bearing can be prevented from being damaged by its high impact resistance, and noise can be generated during the performance. Can be prevented. Furthermore, since the thermoplastic elastomer is a resin, the hardness can be controlled by blending its kind and components. If the hardness of the bearing is too high, it will be difficult to withstand the impact, while if it is too low, shaft shake will occur, which will prevent smooth rotation of the rotating parts. Therefore, such a problem can be avoided by setting the bearing hardness to an appropriate value.

  The invention according to claim 2 is characterized in that, in the support mechanism for the rotating component of the keyboard instrument according to claim 1, the rotating component is at least one of a whippen, a repetition lever, a jack, and a hammer.

  Whippens, repetition levers, jacks, and hammers are the main rotating parts that rotate with key presses on acoustic pianos and the like and have a great influence on performance and touch weight. According to the present invention, the effect of the first aspect can be effectively obtained by configuring the bearing supporting at least one of these rotating parts with the thermoplastic elastomer.

  According to a third aspect of the present invention, in the support mechanism for a rotating component of a keyboard instrument according to the first or second aspect, the bearing is provided at a cylindrical shaft portion that fits into the pin hole, and at one end of the shaft portion. And a collar part that abuts against an edge part of the pin hole when the shaft part is fitted into the pin hole.

  According to this configuration, the bearing can be attached to the pin hole by fitting the shaft portion of the bearing into the pin hole and pushing until the collar portion contacts the edge of the pin hole. It can be carried out. Further, in this case, if the shaft portion can be attached to the pin hole by press-fitting, the bonding is not necessary, and the manufacturing cost can be further reduced by reducing the number of attachment steps.

  In order to achieve the second object, the invention according to claim 4 is a key support mechanism for a keyboard instrument that supports a rotatable key, and is adapted to stand on a heel for supporting the key and the heel. A pin hole is formed on the key and a pin hole that engages the pin. The pin is made of a thermoplastic elastomer, and is provided in the pin hole while sliding along the pin when the key rotates. And a guide material for guiding the key.

  According to the key support mechanism of the keyboard instrument, when the key is depressed, the guide material provided in the pin hole of the key guides the key while sliding along the pin. According to the present invention, the guide material is made of a thermoplastic elastomer. Therefore, the effect by the thermoplastic elastomer can be obtained as in the case of the first aspect. That is, the clearance between the guide member and the pin is maintained almost constant regardless of the wet and dry conditions, so that a stable rotation of the key can be ensured, and accordingly, the touch weight can be stabilized. Further, even when an impact is applied to the guide material, the high impact resistance of the thermoplastic elastomer can prevent the guide material from being damaged, and can also prevent noise during performance. Further, by setting the hardness of the guide material to an appropriate value, a more stable key turning operation can be obtained.

  According to a fifth aspect of the present invention, in the key support mechanism of the keyboard instrument according to the fourth aspect, the key pin hole has a balance pin hole formed at the center of the key and a front formed at the front of the key. The pin is at least one of pin holes, and the pin is at least one of a balance pin with which the balance pin hole is engaged and a front pin with which the front pin hole is engaged.

  When pressing the key, the balance pin with which the balance pin hole engages functions to support the key in a freely rotatable manner, while the front pin with which the front pin hole engages has a function to prevent the lateral movement of the key. Fulfill. Therefore, according to this configuration, the guide member provided in at least one of the balance pin hole and the front pin hole is made of the thermoplastic elastomer, whereby the effect of claim 4 can be effectively obtained.

  The invention according to claim 6 is the key instrument key support mechanism according to claim 4, wherein the guide member has a hollow portion through which the pin is passed, and a main body portion that fits into the pin hole, and a main body portion And a collar portion that abuts against the edge of the pin hole when fitted to the pin hole.

  According to this configuration, the guide material can be attached to the pin hole simply by fitting the main body portion of the guide material into the pin hole and pushing the collar portion up to the edge of the pin hole. Can be done. In addition, as described above, the guide material is conventionally constituted by two sheet-like bushing cloths, whereas the guide material of the present invention is a one-piece molded product. Further, if the main body can be attached to the pin hole by press fitting, the bonding is not necessary. As described above, the manufacturing cost can be reduced by reducing the number of parts and the number of mounting steps.

It is side sectional drawing which shows the keyboard apparatus containing the support mechanism of the rotation components of this invention in a key release state. It is a disassembled perspective view which shows an action. It is a perspective view of a bearing. It is a perspective view which shows a hammer. It is (a) side view and (b) top view which show the bearing of 2nd Embodiment. 6A is a side view and FIG. 6B is a plan view showing a modification of the bearing of FIG. 5. It is a fragmentary perspective view which shows the keyboard apparatus containing the support mechanism of the key by this invention. It is a cross-sectional view of the key support mechanism. FIG. 9 is a cross-sectional view showing a modification of the support mechanism of FIG. It is a perspective view of the guide material of FIG.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a keyboard apparatus for a grand piano including a support mechanism for a rotating component according to a first embodiment of the present invention in a key release state. As shown in the figure, the keyboard device 1 includes brackets 2 and 2 (only one of them is shown) erected on the end of the casket (not shown) in the left-right direction (depth direction in the figure), and the left-right direction. , A whippen rail 3 and a hammer shank rail 4 connected to brackets 2 and 2 at both ends, a plurality of swingable keys 5 (only one shown), and an action provided on the whippen rail 3 6 and a plurality of hammers 7 (only one is shown) provided for each key 5 on the hammer shank rail 4.

  The key 5 is swingably supported by a balance pin (not shown) erected on the bag, and a capstan 5a is screwed into the front side of the wippen rail 3 on the upper surface of the rear part (left part of the figure). It is.

  The action 6 includes a wippen 12, a jack 13 and a repetition lever 14 as rotating parts. The whippen 12 is rotatably supported by the whippen flange 11 screwed to the whippen rail 3 as a supporting component. The jack 13 and the repetition lever 14 are rotatably supported by the wippen 12 as a supporting component.

  As shown in FIG. 2, left and right mounting portions 11a and 11a branched in a bifurcated manner are provided on the upper portion of the Wippen frenzy 11, and each mounting portion 11a has a pin hole 11b penetrating in the left-right direction. Is formed. In each pin hole 11b, a bearing 15 is fitted and fixed by, for example, adhesion.

  As shown in FIG. 3, the bearing 15 is formed in a cylindrical shape having a through hole 15a. The bearing 15 is formed of a thermoplastic elastomer molded product. As this thermoplastic elastomer, for example, a styrene elastomer, an olefin elastomer, a polyamide elastomer or a urethane elastomer is used. The thermoplastic elastomer hardly expands due to moisture absorption or shrinks due to moisture release, and has rubber-like elasticity at room temperature.

  As shown in FIG. 2, the whippen 12 includes a main body portion 16 extending in the front-rear direction, a lever flange portion 17 extending upward from the central portion, a heel portion 18 protruding downward from the central portion, and the like. Left and right jack mounting portions 16a and 16a branched in a bifurcated manner are provided at the front end portion of the main body portion 16, and left and right lever mounting portions 17a and 17a branched in a bifurcated shape are provided at the upper portion of the lever flange portion 17, respectively. In the jack mounting portion 16a and the lever mounting portion 17a, a pin hole 16b and a pin hole 17b penetrating in the left-right direction are formed. The above-described bearing 15 shown in FIG. 3 is also fitted into these pin holes 16b and 17b, and is fixed by, for example, adhesion. Further, a hole 21 penetrating in the left-right direction is formed in the rear end portion of the main body portion 16. The rear end portion of the main body portion 16 is engaged between the attachment portions 11 a and 11 a of the whippen frenzy 11, and a center pin 22 (pin) is inserted into each bearing 15 and the hole 21. The center pin 22 is fixed to the hole 21 of the whippen 12 and is rotatably engaged with each bearing 15 of the whippen flange 11. Accordingly, the wippen 12 is rotatably supported by the wippen frenzy 11. The wippen 12 is placed on the capstan 5a of the key 5 through the heel portion 18 (see FIG. 1).

  The repetition lever 14 extends in the front-rear direction, and has a hole 23 penetrating in the left-right direction at the center and a jack guide hole 24 penetrating in the up-down direction at the front end. The central portion of the repetition lever 14 is engaged between the lever mounting portions 17 a and 17 a of the wippen 12, and a center pin 22 is inserted into each bearing 15 and hole 23. The center pin 22 is fixed to the hole 23 of the repetition lever 14 and is rotatably engaged with the bearings 15 of the lever mounting portion 17. Thus, the repetition lever 14 is rotatably supported by the wippen 12. Further, a repetition screw 25 penetrating in the vertical direction is screwed into the rear end portion of the repetition lever 14, and a repetition button 26 is attached to the lower end portion thereof.

  The jack 13 is formed in an L shape by a base portion 13a, a hammer push-up portion 13b extending upward from the base portion 13a, and a regulating button contact portion 13c extending forward from the base portion 13a. A hole 27 penetrating in the left-right direction is formed in the base portion 13a. The base portion 13 a is engaged between the jack mounting portions 16 a and 16 a of the wippen 12, and the center pin 22 is inserted into each bearing 15 and the hole 27. The center pin 22 is fixed to the hole 27 of the jack 13 and is rotatably engaged with each bearing 15. Thereby, the jack 13 is rotatably supported by the wippen 12. Further, the hammer push-up portion 13b is engaged with the jack guide hole 24 of the repetition lever 14 at the tip portion, and a jack button screw 28 penetrating in the front-rear direction is screwed into the middle portion in the vertical direction. A jack button 29 is attached to the end. A spoon 31 is provided on the upper surface of the body portion 16 of the wippen 12 so that the jack button 29 abuts immediately behind the jack 13.

  A repetition spring 32 that urges the jack 13 and the repetition lever 14 counterclockwise in the same figure is attached to an intermediate portion in the vertical direction of the lever flange portion 17 of the whippen 12. Due to the urging of the repetition spring 32, the repetition button 26 of the repetition lever 14 contacts the upper surface of the body portion 16 of the wippen 12 and the jack button 29 of the jack 13 contacts the spoon 31 in the key release state shown in FIG. Touching.

  As shown in FIG. 4, the hammer 7 is composed of a hammer shank 8 extending in the front-rear direction and a hammer head 9 provided integrally at the rear end. A shank roller 36 is provided at the front end portion of the lower surface of the hammer shank 8, and left and right hammer shank flange mounting portions 7a, 7a branched in a bifurcated manner are provided at the front side thereof. Each hammer shank flange mounting portion 7a is formed with a pin hole 7b penetrating in the left-right direction. The above-described bearing 15 shown in FIG. 3 is fitted into each pin hole 7b, and is fixed by, for example, bonding. . On the other hand, a hammer shank flange 33 is screwed to the hammer shank rail 4 for each key 5 (see FIG. 1). In the hammer shank flange 33, a hole 34 penetrating in the left-right direction is formed at the rear end portion, and a drop screw 35 is screwed in from the lower side to the front side. The center pin 22 is inserted into each bearing 15 and the hole 34 with the hammer shank flange mounting portions 7a and 7a engaged with the rear end portion of the hammer shank flange 33. The center pin 22 is fixed to the hole 34 of the hammer shank flange 33 and is rotatably engaged with each bearing 15. Thereby, the hammer 7 as a rotating part is supported by the hammer shank flange 33 as a supporting part so as to be rotatable. The shank roller 36 is placed on the edge of the jack guide hole 24 of the repetition lever 14 in the key release state (see FIG. 1). A regulating button 38 is provided for each key 5 on the lower surface of the hammer shank rail 4 via a regulating rail 37.

  With the above configuration, when the key 5 is depressed, the capstan 5a pushes up the heel portion 18 so that the wippen 12 rotates counterclockwise around the rear end portion. And the repetition lever 14 also moves upward together. Along with these movements, the repetition lever 14 first pushes up the hammer 7 while sliding the shank roller 36, and rotates the hammer 7 upward. Next, the front end portion of the repetition lever 7 abuts on the drop screw 35, and the repetition lever 7 rotates clockwise around the upper end portion of the lever flange portion 17, whereby the hammer push-up portion 13 b of the jack 13 is moved to the shank roller 36. The hammer 7 is pushed up through. Thereafter, when the hammer 7 rotates until just before striking the string S stretched upward, the regulating button abutting portion 13 c abuts on the regulating button 38, whereby the jack 13 is connected to the main body portion 16. Rotating clockwise around the front end, the contact with the shank roller 36 is released. As a result, the hammer 7 is disconnected from the action 6 and the key 5 and hits the string S in a freely rotating state.

  When the key 5 is released, the hammer 7 and the whippen 12 rotate by their own weight, and the jack 13 and the repetition lever 14 are urged by the repetition spring 32 to rotate in the opposite direction to the key depression, respectively. Thus, the key release state shown in FIG. 1 is restored.

  As described above, when the key 5 is depressed, the whippen 12, the jack 13, the repetition lever 14 and the hammer 7 as rotating parts correspond to the supporting parts via the bearings 15 and the center pin 22 that are engaged with each other. The key 5 is supported by being depressed and released. In the present embodiment, the bearing 15 is formed of a molded product of thermoplastic elastomer, and unlike natural fibers, it hardly expands due to moisture absorption or shrinks due to moisture release as described above. For this reason, the clearance between the center pin 22 and the bearing 15 is maintained substantially constant regardless of the change in humidity, so that the rotating component does not have difficulty in rotating and does not run out. Stable operation can be secured. Accordingly, the touch weight of the key 5 can be stabilized.

  In addition, these rotating parts are main parts that greatly affect performance, touch weight, and the like. In this embodiment, all the bearings 15 of these rotating parts are made of a thermoplastic elastomer. Therefore, the above-described effect can be obtained effectively. In addition, it is not necessary to perform a drying process after immersing the bushing cloth in water containing a surfactant, which has been conventionally performed to remove the influence of wet and dry, and the manufacturing cost can be reduced accordingly. .

  The thermoplastic elastomer is rubbery and elastic at room temperature. Therefore, even when an impact is applied to the bearing 15 when a key is pressed during performance or when a piano is transported or adjusted, the bearing 15 can be prevented from being damaged by its high impact resistance and noise during the performance can be prevented. Occurrence can be prevented. Furthermore, since the thermoplastic elastomer is a resin, the hardness can be controlled by blending its kind and components. If the hardness of the bearing 15 is too high, it will be difficult to withstand the impact, while if it is too low, shaft shake will occur, which will prevent smooth rotation of the rotating parts. Therefore, such a problem can be avoided by setting the hardness of the bearing 15 to an appropriate value.

  FIG. 5 shows a bearing according to a second embodiment of the present invention. The bearing 41 is made of the same thermoplastic elastomer as the bearing 15 of the first embodiment, and a shaft portion 42 that fits into a pin hole (7b, 11b, 16b, 17b, hereinafter referred to as “pin hole 7b etc.”); It is comprised by the one-piece molded product which has the collar part 43 provided in the end of the axial part 42 integrally. The shaft portion 42 has a cylindrical shape having a hole 41a, and an outer peripheral portion thereof is formed in a bellows shape having a concave portion 42a and a convex portion 42b. The diameter of the convex portion 42b is substantially the same as the diameter of the pin hole 7b or the like. The collar portion 43 has a circular dish shape, has a larger diameter than the convex portion 42 b of the shaft portion 42, and the hole 41 a of the shaft portion 42 extends to the collar portion 43.

  According to this configuration, the bearing 41 is simply coated with an adhesive, the shaft portion 42 is fitted into the pin hole 7b and the like, and the collar portion 43 is pushed in until it comes into contact with the edge portion such as the pin hole 7b. Can be attached to the pin hole 7b or the like, and the bearing 41 can be easily attached. Moreover, since the friction at the time of pushing in the shaft part 42 is reduced by the recess 42a of the shaft part 42, the shaft part 42 can be easily pushed into the pin hole 7b or the like. Further, since the shaft portion 42 can be reliably brought into contact with the pin hole 7b or the like by the convex portion 42b of the shaft portion 42, the adhesion can be stably performed. Further, the diameter of the convex portion 42b of the shaft portion 42 is set to a value slightly larger than the diameter of the pin hole 7b and the like, and the shaft portion 42 is attached to the pin hole 7b or the like by press-fitting using the elasticity of the thermoplastic elastomer. Is also possible. As a result, no bonding is required, and the manufacturing cost can be further reduced by reducing the number of mounting steps accordingly.

  FIG. 6 shows a modification of the bearing. This bearing 51 is provided with four protrusions 52 on the surface on the shaft part 42 side of the collar part 43 of the second embodiment, and these protrusions 52 are arranged at equal intervals in the circumferential direction. . On the other hand, four recesses (not shown) in which the protrusions 52 of the bearing 51 can be engaged are formed at the edge of the pin hole 7b or the like into which the bearing 51 is fitted. With the above configuration, when the shaft portion 42 is pushed into the pin hole 7b or the like, the projections 52 of the bearing 51 can be fitted into the corresponding recesses to prevent the bearing 51 from rotating. Can be installed in a stable state.

  In the example described so far, the present invention is applied to all of the whippen 12, the jack 13, the repetition lever 14 and the hammer 7 of the grand piano. However, the present invention may be applied to some of them. Good. Moreover, you may apply this invention to the other rotation components rotated with key pressing. For example, in general, a grand piano is supported by a damper flange, and a damper lever that rotates by being pushed up at the rear end of the key when the key is pressed, or a damper that is supported by the damper lever and rotates with the rotation. Since the wire flange is provided, the present invention may be applied using these damper levers and damper wire flanges as rotating parts. Further, the present invention is not limited to a grand piano but can be applied to an upright piano. The present invention may also be applied using the whippen, jack, hammer and damper lever as rotating parts.

  FIG. 7 shows an upright piano keyboard apparatus including a key support mechanism according to the present invention. As shown in the figure, the keyboard device 61 has a balance pin 64 (pin) and a front pin 65 (pin) provided so as to stand up in the center 62 (筬) and the front 63 (筬), respectively. A key 66 that engages with the pin 64 and the front pin 65 is provided.

  The key 66 includes a key body 71 extending in the front-rear direction, an acrylic key cover 73 adhered to the front half of the key body 71, and the like. The key body 71 is made of a relatively light and elastic wood material such as spruce or pine. An intermediate seat plate 74 made of a harder wood material is bonded to the center of the upper surface of the key body 71 for reinforcement. In addition, a balance pin hole 67 (pin hole) is formed in the central portion of the key body 71 so as to penetrate the intermediate seat plate 74 from the key body 71 in the vertical direction. A front pin hole 68 (pin hole) that opens downward is formed in the front portion of the key body 71. The key 66 is swingably supported by the balance pin 64 with the balance pin hole 67 engaged with the balance pin 64 and the front pin hole 68 engaged with the front pin 65, respectively.

  As shown in FIG. 8, the balance pin holes 67 are formed symmetrically. The balance pin hole 67 includes a round hole 75 at the lower end portion of the key body 71 and a long hole portion 76 that extends to the upper side and extends in the front-rear direction. The width of the long hole portion 76 is narrow at the lower end portion and is widened at the upper end portion to form a counterbore 76a.

  Guide materials 72 are attached to the left and right inner surfaces of the long hole portion 76 of the balance pin hole 67 by bonding or the like. Each guide member 72 is formed of a thermoplastic elastomer molded product, like the bearing 15 of the first embodiment, and is formed of, for example, a styrene elastomer, an olefin elastomer, a polyamide elastomer, or a urethane elastomer. The guide member 72 has a shape along the left and right inner surfaces of the long hole portion 76 and has a length in the front-rear direction substantially equal to the long hole portion 76. The interval between the attached guide members 72 is substantially equal to the diameter of the balance pin 64 at the lower end portion, so that the lower end portions of the guide members 72 and 72 are slidable with respect to the balance pin 64. . Further, as a result of the upper end portion of the guide member 72 being accommodated in the counterbore 76 a of the long hole portion 76, the upper surface of the guide member 72 is flush with the middle seat plate 74. Note that left and right guide members (not shown) having a shape along the inner surface are similarly attached to the front pin hole 68 of the key body 71, and both guide members engage with the front pin 65, In contrast, it is slidable.

  With the above configuration, when the key 66 is depressed, the guide materials 72 and 72 provided in the balance pin hole 67 of the key 66 and the guide material provided in the front pin hole 68 (hereinafter referred to as “guide material 72 and the like”). ) Guides the key 66 while sliding along the balance pin 64 and the front pin 65. At this time, the front pin 65 that engages with the front pin hole 68 functions to prevent the key 66 from shaking left and right. According to this embodiment, the guide material 72 etc. are comprised with the thermoplastic elastomer. Therefore, the effect by a thermoplastic elastomer can be acquired similarly to the case of 1st Embodiment. That is, the clearance between the guide material 72 and the balance pin 64 and the front pin 65 is maintained almost constant regardless of the wet and dry conditions, so that a stable rotation operation of the key 66 can be ensured. Touch weight can also be stabilized. Further, even when an impact is applied to the guide material 72 and the like, the high impact resistance of the thermoplastic elastomer can prevent the guide material 72 and the like from being damaged, and can also prevent noise during performance. Furthermore, by setting the hardness of the guide member 72 or the like to an appropriate value, a more stable rotation of the key 66 can be obtained.

  9 and 10 show a modification of the guide material. The guide material 81 is mainly different from the guide material 72 described above in that it is configured as a one-piece, whereas the guide material 72 is configured as a pair. That is, the guide material 81 is formed of a one-piece molded product made of the same thermoplastic elastomer as the guide material 72. As shown in FIG. 10, the guide member 81 has a shape complementary to the long hole portion 76 of the balance pin hole 67 and has a hole 83 (hollow portion) penetrating in the vertical direction. And a flange portion 85 provided at the upper end portion thereof. The guide member 81 having the above configuration is coated with an adhesive in advance, the main body portion 84 is fitted into the balance pin hole 67, and the collar portion 85 is simply pushed in until it comes into contact with the counterbore 76a of the balance pin hole 67. The guide pin 81 can be easily attached to the balance pin hole 67. Further, the width of the guide member 81 is set to a value slightly larger than the width of the long hole portion 76 of the balance pin hole 67, and the guide member 81 is attached to the balance pin hole 67 by press-fitting using the elasticity of the thermoplastic elastomer. It is also possible. Thereby, no adhesion is required. Moreover, since the guide material 81 is comprised by the one-piece molded product, the manufacturing cost of a piano can be reduced by reducing a number of parts and an installation man-hour. A one-piece guide material (not shown) having a shape complementary to the front pin hole 68 is similarly attached to the front pin hole 68 of the key body 71.

  In addition, this invention can be implemented in various aspects, without being limited to the described embodiment. For example, a fluoropolymer or the like may be added to the thermoplastic elastomer in order to smoothly rotate the bearing and slide the guide material.

  The embodiment is an example of an acoustic piano, but the present invention can of course be applied to other types of keyboard instruments such as an organ, an electronic piano, and an electronic organ. In addition, the detailed configuration can be changed as appropriate within the scope of the gist of the present invention.

Explanation of symbols

7 Hammer (Rotating parts)
7b Pin hole 11 Whippen frenzy (support parts)
11b Pin hole 12 Whippen (turning parts, support parts)
13 Jack 14 Repetition lever (turning part)
15 Bearing 16b Pin hole 17b Pin hole 22 Center pin (pin)
33 Hammer Shank Frenzy (support parts)
41 Bearing 42 Shaft 43 Brim 51 Bearing 62
63 筬 (筬)
64 Balance pin (pin)
65 Front pin
66 Key 67 Balance pin hole (pin hole)
68 Front pin hole (pin hole)
72 Guide material 81 Guide material 83 Hole (hollow part)
84 Body 85 Flange

Claims (6)

A support mechanism for a rotating component of a keyboard instrument that supports a rotating component that rotates with a key press,
A support component for supporting the rotating component;
A pin hole is formed in one of the rotating part and the supporting part,
A cylindrical bearing composed of a thermoplastic elastomer and fixed to the pin hole;
A pin that is provided on the other of the rotating component and the support component and that is rotatably engaged with the bearing;
A support mechanism for rotating parts of a keyboard instrument, comprising:   The support mechanism for a rotating component of a keyboard instrument according to claim 1, wherein the rotating component is at least one of a whippen, a repetition lever, a jack, and a hammer.   The bearing is provided at a cylindrical shaft portion that fits into the pin hole and one end of the shaft portion, and abuts against an edge portion of the pin hole when the shaft portion is fitted into the pin hole. The support mechanism for a rotating part of a keyboard instrument according to claim 1 or 2, characterized in that it is formed of a one-piece molded product having a flange portion. A key support mechanism for a keyboard instrument that supports a rotatable key,
A cage for supporting the key;
A pin provided to stand on the fence,
The key has a pin hole that engages with the pin,
A guide material that is made of a thermoplastic elastomer, is provided in the pin hole, and guides the key while sliding along the pin when the key rotates.
A mechanism for supporting a key of a keyboard instrument, comprising: The pin hole of the key is at least one of a balance pin hole formed in a central part of the key and a front pin hole formed in a front part of the key,
5. The keyboard instrument key support mechanism according to claim 4, wherein the pin is at least one of a balance pin engaged with the balance pin hole and a front pin engaged with the front pin hole. The guide member has a hollow portion through which the pin is passed, and a main body portion that fits into the pin hole, and a collar portion that abuts on an edge portion of the pin hole when fitted into the main body portion. 5. The keyboard instrument key support mechanism according to claim 4, wherein the key instrument has a one-piece molded product.

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