JP5228544B2 - Keyboard instrument lid opening and closing device - Google Patents

Description

The present invention relates to a lid opening / closing device for a keyboard instrument that covers the keyboard of the keyboard instrument.
In particular, it is suitable for electronic keyboard instruments, but can also be applied to acoustic keyboard instruments such as pianos and organs.

2. Description of the Related Art An electronic keyboard instrument is known that includes a lid that covers the keyboard.
For example, the electronic keyboard instrument described in Patent Document 1 includes a rotary lid (front cover), the lower wall of the lid extends to the rear, and a pivot fulcrum portion at both ends of the rear end portion. A mounting plate having a (fitting hole) is fixed. On the other hand, a locking portion is provided by extending to the rear portion at both ends of the lid in the key arrangement direction, and the tension coil spring (elastic member) is locked to the locking portion and the pin on the shelf plate, thereby buffering ( (Damper) mechanism. This locking portion is on the opposite side of the rotation fulcrum portion.
This tension coil spring provides a biasing force that acts in a direction that prevents movement of the lid in a state immediately before the keyboard is completely closed with the lid and a state immediately before the keyboard is fully opened by tilting the lid backward. As a result, the risk that the lid suddenly falls forward or behind the instrument and pinches the finger is avoided. The biasing force of this tension coil spring is easy to open with a light force because it is applied in the opening direction when opening the fully-closed lid, and this biasing force is light because it is applied in the closing direction when closing the fully-opened lid. Easy to close with force.

In the electronic keyboard instrument described above, a rotating device having a damper function is attached to the side plate. A rectangular shaft is fitted into the fitting hole as the rotation fulcrum described above. When this shaft rotates in the rotation support portion, resistance to the rotation of the shaft is given by the contact resistance of the internal member, and the rotation operation is slowed down. Such a rotating device having a damper function is known from Patent Document 2, and includes a one-way clutch mechanism, an oil damper, a torque shaft bush, and the like in which torque is applied only in one direction. Such a pivoting device closes the lid slowly.
Incidentally, if only such a rotating device is used, the lid becomes heavy when the lid is opened, so the above-described tension coil spring is used in combination.

The above-described tension coil spring has a large spring constant or a high initial tension in order to support the lid (front cover) of the above-described electronic keyboard instrument. However, it is difficult to manually attach such a tension coil spring to the pin in a stretched state.
Therefore, it is necessary to hook the end of the tension coil spring to the pin in the intermediate position where the extension of the tension coil spring is the minimum (the solid line position of the front cover in FIG. 3 of Patent Document 1) during the entire opening / closing movement of the lid. is there. However, in this intermediate position, the front cover is largely inclined toward the front side. As a result, there is a risk that a hand may be caught in the front cover if the end is not hooked on the pin. For this reason, it is necessary to perform the hooking work while supporting the front cover by hand, so that the work is difficult.
JP 2004-302419 A JP 11-175053 A

  The present invention was made to solve the above-described problems, and attaches a tensile force generation elastic element for a damper that prevents a lid that covers the keyboard portion from abruptly falling down during manufacture. An object of the present invention is to provide a lid opening / closing device for a keyboard instrument.

The invention according to claim 1 is a lid opening / closing device for a keyboard instrument having a keyboard part, a lid that covers the upper surface of the keyboard part, and a keyboard accommodating part that accommodates the keyboard part, wherein the keyboard accommodating part in the interior of the keyboard portion fixing portion to said keyboard housing part located on the back side is fixed than the tensile force generated acoustic elements multiple, SL before the tensile force-generating resilient element of said plurality of fixed One or a plurality of elastic element attachment members for attachment to the portion, and each of the tensile force generating elastic elements has one end disposed at the rear end of the lid and the other end disposed at the elastic element attachment member. By storing elastic energy commensurate with the release of potential energy due to vertical movement of the lid when the lid is closed to the near side and / or when the lid is opened to the back side. When the lid is closed to the front side and / or the lid is The functions as a damper when finishes opening, said one end and the other end of each tension generated acoustic element is disposed in an oblique or orthogonal direction with respect to the moving direction of the lid, and wherein the plurality of The tensile force generating elastic elements are arranged in parallel so that the component of the urging force orthogonal to the moving direction of the lid body substantially cancels .

Therefore , it is possible to prevent the behavior that the lid body falls down rapidly.
That is, when the keyboard is a keyboard instrument that is closed by the weight of the lid when the lid is closed to the near side, it is possible to prevent the lid from falling suddenly. Moreover, when the lid is finished opening, the same behavior can be prevented even in the case of a keyboard instrument having a structure that is further opened rearward by the weight of the lid.
In the keyboard instrument manufacturing process, if the lid is closed or the lid is too open, a tool cannot be inserted between the lid and the keyboard housing part, or the fixed part cannot be seen. However, it is easy to temporarily fix.
If it is necessary to move the lid so that the tool can be inserted between the lid and the keyboard housing, or the fixed part can be seen, move the lid after temporary fixing. By doing so, the tensile force generating elastic element can be easily extended. Further, after the temporary fixing, since the positioning is almost completed, fixing work such as screwing becomes easy.
Further, in the manufacturing process of the keyboard instrument, one end and the other end of the tensile force generating elastic element are disposed obliquely or orthogonally to the moving direction of the lid, so that the moving direction of the lid is As the angle formed by the direction in which the tensile force generating elasticity is arranged approaches 90 ° (vertical), the lid moving direction component of the biasing force of the tensile force generating elastic element becomes smaller. It will be easy.
On the other hand, as the angle formed by the direction in which the tensile force generating elastic element is arranged with respect to the moving direction of the lid is closer to 0 °, the component of the biasing force of the tensile force generating elastic element becomes larger in the moving direction of the lid. Will not be damaged.

Tensile force generated acoustic element before Kifuku number, as components of the biasing force perpendicular to the moving direction before Kifutatai is largely offset, in which are arranged in parallel. Thereby, the force in the left-right direction of the lid is balanced. Therefore, there is no need for a regulating member such as a guide for moving the lid body in a desired moving direction without being biased in the left-right direction, and friction with the regulating member can be eliminated.
The plurality of tensile force generating elastic elements are arranged in line symmetry with respect to the moving direction of the lid, in other words, a pair of elements arranged on a mirror object. Therefore, it is easy to cancel the biasing force component orthogonal to the moving direction of the lid.

  The plurality of tensile force generation elastic elements are a plurality of independent and independent tensile force generation elastic elements, and at least one of the one or the plurality of elastic element mounting members includes the plurality of independent and independent tensile forces. Among the generated elastic elements, at least two other end portions are attached. Accordingly, at least two tensile force generating elastic elements that are separated and independent are used, but since the other end portions thereof are attached to one elastic element mounting member that is common to both of them, in the manufacturing process of a keyboard instrument. The difficult operation of attaching the elastic element mounting member to the fixed portion is completed in one time. As a result, it is the same as the operation of attaching the tensile force generating elastic element composed of two elements that are not separated and independent to the fixing portion via one elastic element attaching member.

  The locking portion of the fixing portion is, for example, a locking hole or a locking projection, and the locked portion of the elastic element mounting member is an engagement projection or engagement that engages with the above-described engagement hole or engagement projection. It is a hole. For example, the elastic element mounting member may have a mounting hole and be configured to be screwed to the fixing portion via the mounting hole.

INDUSTRIAL APPLICABILITY The present invention has an effect that it is possible to prevent the behavior of the lid body, which has a risk of pinching the finger, that the lid body falls down rapidly.
Moreover, there is an effect that it is safe and easy to attach the tensile force generating elastic element at the time of manufacture.
For example, since the temporary fixing locking structure is provided, if the temporary fixing is performed, the elastic element mounting member may be fixed to the fixing portion as it is or after being more precisely aligned.
For example, by disposing one end and the other end of the tensile force generating elastic element obliquely or perpendicularly to the moving direction of the lid, the component in the moving direction of the lid of the urging force of the tensile force generating elastic element is reduced. Since the elastic element attachment member can be attached to the fixed portion in the state, there is an effect that the operation is simplified.

FIG. 1 is a first cross-sectional view for explaining a first embodiment of the present invention. This cross-sectional view is a cross-sectional view of the keyboard instrument main body (keyboard storage portion) 1 shown in the arrow AA in FIG.
In particular, the rotation support portion 25 and the guide member 27 in the left side plate are shown, and illustrations of structures not related to the present invention are omitted.
In this figure, only the keyboard instrument main body 1 is shown. An electronic keyboard instrument is assembled by mounting and fixing the keyboard instrument main body 1 on a support (not shown) (including a leg, a speaker box, and a pedal unit).

The keyboard instrument main body 1 is formed in a box shape by a shelf board 2, a mouth bar 3, left and right side plates 4 (the left side plate is visible), an upper back plate 5 and an upper front unit 6, and a plurality of them are formed therein. A keyboard unit 9 in which white keys 7 and black keys 8 are arranged is accommodated. In the keyboard unit 9, a plurality of white keys 7 and black keys 8 constitute a keyboard part, supported by a key frame (not shown), and a key action mechanism is provided below the keyboard part. There is an operation panel 10 (see FIG. 2) in the upper part of the keyboard unit 9 in the depth direction. Both end portions of the key arrangement are the time tree front part 11, and the members that form the time tree are integrated with the time tree rear part 12 located on the left and right sides of the operation panel 10.
An input / output terminal box 13 and a lower back plate fixing block 14 are attached to the lower surface of the shelf board 2.

A lid is provided to cover the upper surface of the keyboard portion on which a plurality of white keys 7 and black keys 8 are arranged. The illustrated lid has a front lid 21 and a rear lid 22, and on the surface side of both, the upper side of the rear end of the front lid 21 and the upper side of the front end of the rear lid 22 are connected by a hinge 23. It is connected in a foldable manner with a line parallel to the arrangement direction as an axis.
In the front lid 21, 21 a is a front wall, 21 b is a music stand, and is attached to the back surface of the front lid 21. In a state where the lid is closed, the front wall 21a hangs down on the mouth stick 3 and the music stand 21b is folded. A pair of left and right arms 24 are arranged on the left and right side surfaces (both side surfaces in the key arrangement direction) at the rear end of the front lid 21, and extend along the side surface of the front lid 21. . In this figure, the left arm 24 is visible.

  The arm 24 is attached to the front lid 21 by the mounting plate 24a being embedded in a groove formed on the back surface of the front lid 21 and screwed. The mounting plate 24a extends obliquely downward in the drawing along the back surface to form a mounting plate extending portion 24b, and is orthogonal to the rotating plate 24c on the side perpendicular to the key arrangement direction on the side of the side plate 4 side. Are connected. In the illustrated example, the rotating plate 24 c is on the same plane as the left and right side surfaces of the front lid 21. A rotating fulcrum portion 24d is provided at the lower portion of the rotating plate 34c. Accordingly, the arm 24 extends from the left and right end portions of the front lid 21 below the rear end of the front lid 21, and a pivot fulcrum portion 24 d is formed on this arm.

The rotation fulcrum portion 24d is, for example, a bearing hole or a rotation shaft. One rotation fulcrum portion 24d of the left and right arms 24 may be a bearing hole and the other may be a rotation shaft. The rotation fulcrum portion 24 d is located below the hinge 23. Reference numeral 25 denotes a rotation support portion which is attached to the inside of a groove formed in the side plate 4 and has a structure for supporting the rotation fulcrum portion 24d. The arm 24 rotates in the gap between the side plate 4 and the side surface of the timepiece rear part 12. A buffer member 4 a for preventing contact with the arm 24 may be attached to the side plate 4.
The rotation fulcrum part 24d may be a rotation support part 25 provided with a buffer mechanism (such as a one-way clutch).

On the other hand, an L-shaped member 26 made of metal or the like is attached to the left and right ends of the lower surface in the vicinity of the rear end of the rear lid 22, and a protruding body 26 a is attached to the L-shaped member 26. It is provided in the direction. On the other hand, a guide member 27 is attached to the inner side surface of the side plate 4. The illustrated guide member 27 is a plate material having an open upper portion and a horizontal guide groove 27a that is elongated in the longitudinal direction of the key. The upper opening is blocked by the bottom plate of the L-shaped member 28 after the protrusion 26a is inserted.
Since the protrusion 26a described above is fitted in the guide groove 27a, the rear lid 22 is guided so as to move substantially horizontally in the longitudinal direction of the key.

  When attaching the rear cover 22 to the keyboard instrument main body 1, after attaching the damper unit 22 described with reference to FIG. 2, the projecting body 26 a is fitted into the guide groove 27 a and the L-shaped member 28 is attached. Finally, the upper front unit 6 is placed on the rear portion of the side plate 4 to complete the assembly of the musical instrument main body 1 and is placed and fixed on a support (not shown). Reference numeral 29 denotes a buffer member between the upper front unit 6 and the side plate 4.

The lid formed by the front lid 21 and the rear lid 22 described above has a structure that is also employed in Non-Patent Documents 1 and 2 cited in the background art.
When the performer lifts the front lid 21, the front lid 21 rotates clockwise around the rotation fulcrum portion 24d, so that the keyboard portion (white key 7, black key 8) and the operation panel 10 are exposed. . In conjunction with the rotation of the front lid 21, the rear lid 22 has a radius as the distance between the rotation fulcrum portion 24d and the hinge 23, and its front end slightly pivots clockwise, while its entirety is a musical instrument. Backward, move in a straight line while maintaining a substantially horizontal state. As a result, the exposed part becomes wider.
However, since the above-described structure alone does not have a damper mechanism, the front lid 21 suddenly falls forward (in front of the musical instrument) when the keyboard part is completely closed. Therefore, in this embodiment, as shown in FIG. 2, the damper unit 32 as one or a plurality of tensile force generating elastic elements includes the rear rear end portion of the rear lid 22 and the keyboard instrument main body (keyboard housing portion) 1. Between the fixed part located on the back side (back of the musical instrument) from the keyboard part.

FIG. 2 is a second cross-sectional view illustrating the first embodiment of the present invention. FIG. 3 is a cross-sectional view of the key from the right side to the left side in the center of the arrangement direction of the keys, as in FIG. 1.
In particular, the fixed base 31 and the damper unit 32 arranged in the center of the key arrangement direction are shown, and illustrations of structures not related to the present invention are omitted.
In the figure, the same parts as those in FIG. Reference numeral 31 denotes a fixed base, 32 denotes a damper unit, and 33 denotes a spacer (plate). The fixing base 31 is fixed to the shelf plate 2 at the center in the key arrangement direction, and is fixed to the upper back plate 5 via a spacer 33.

As will be described in detail with reference to FIGS. 3 to 5, the damper unit 32 includes tension coil springs (tensile force generating elastic elements) 41 and 44 (only the left tension coil spring 41 is visible), and a spring mounting member 42. , 45 and a spring mounting member (elastic element mounting member) 43.
The tension coil springs 41 and 44 are arranged in parallel and symmetrically with respect to the moving direction of the lid (front-rear direction, the direction of the center line 61 between the elements shown in FIG. 5) in a line-symmetric manner with the same characteristics. is there. The spring attachment members 42 and 45 are for attaching one end portions (41a and 44a in FIG. 3) of the tension coil springs 41 and 44 to the lower surface (rear surface) of the rear end portion of the rear lid 22. The spring attachment member 43 attaches the other end portions (41b, 44b in FIG. 3) of the tension coil springs 41, 44 to the fixed base 31, and in the illustrated example, the keyboard instrument body portion (keyboard housing portion) 1 Is attached to a position in the vicinity of the upper back plate 5 that is farthest away from the keyboard portion (white key 7, black key 8).
The horizontal portion (fixed portion) 31 a of the fixing base 31 has a long hole (locking portion) 31 b for temporarily fixing the protruding portions (locked portions) 43 d and 43 e of the spring mounting member 43, and the spring mounting member 43. Screw mounting holes 31c and 31d are formed for fixing the screw.

The tension coil springs 41 and 44 accumulate elastic energy commensurate with the release of potential energy caused by the vertical movement of the lid when the lid is closed in the process of covering the top surface of the keyboard part. By displacing so as to release elastic energy when starting to open, it functions as a damper when the lid ends.
FIG. 3 is an enlarged perspective view showing the operation of temporarily fixing the spring mounting member 43 shown in FIG. In the figure, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals.
FIG. 4 is an explanatory view showing an operation of fixing the spring mounting member 43 shown in FIG. 2 to the horizontal portion 31 a of the fixing base 31. FIG. 4A is a partially enlarged view of the circular portion shown in FIG. FIG. 4B is a cross-sectional view for explaining the basic structure of the spring receiving member.

With reference to FIG. 3, the fixed base 31 is demonstrated first. The fixing base 31 is a sheet metal bent, but may be a resin molded product. In the latter half of the horizontal portion 31a, there are formed a long hole 31b which is a locking portion for temporary fixing and serves as a position portion for fixing the spring, and further, screw attachment holes 31c and 31d are formed on the rear end side. Yes. The long hole 31b is long in the left-right direction (key arrangement direction).
A front leg 31e is formed on the front side (in front of the musical instrument) of the horizontal portion 31a, and a mounting portion 31f is formed on the lower end thereof. Rear legs 31g and 31h are formed on the rear end side (instrument rear) of the horizontal portion 31a, and attachment portions 31i and 31j are formed on the lower ends of the rear legs 31g and 31h, respectively. Further, a mounting portion 31k is formed at the rear end of the horizontal portion 31a.

Next, the damper unit 32 will be described. Since the damper unit 32 has a symmetrical shape, the structure on the left side will be described in detail.
The spring mounting member 42 on the left side has vertical portions 42d and 42e at both ends of the horizontal portion 42a, and mounting plates 42b and 42c are formed through these vertical steps.
A spring receiving member 51 described later with reference to FIG. 4 is supported on the lower surface of the horizontal portion 42a. By attaching a round hook which is one end portion 41a of the tension coil spring 41 to the spring receiving member 51, the tension coil spring 41 is attached to the spring attachment member 42 so as to be rotatable on a horizontal plane.
. Screws are passed through holes formed in the mounting plates 42b and 42c, and the mounting plate 42 is fixed to the rear end of the rear surface of the rear lid 22 with screws.

On the other hand, the spring mounting member 43 is of a left-right symmetric shape having vertical portions 43h and 43i at both ends of the horizontal portion 43a and mounting plates 43b and 43c formed through the vertical steps.
A spring receiving member 51 is supported on the mounting plates 43b and 43c. By attaching the round hooks which are the other end portions 41 b and 44 b of the tension coil springs 41 and 44 to the spring receiving member 51, the tension coil springs 41 and 44 can rotate on the horizontal plane with respect to the spring mounting member 43. It is attached.
The horizontal portion 43a has two protrusions 43d and 43e formed by bending the front end thereof vertically downward, and two screw insertion holes 43f and 43g on the inner side (see FIG. 5). Is formed.

Next, the structure of the spring receiving member 51 and the structure of attaching the spring receiving member 51 to the spring mounting member 43 will be described with reference to FIG. In addition, the damper unit 32 shown in FIG. 3 includes three spring receiving members 51 in addition to these, but all have the same structure.
As shown in FIG. 4B, the spring receiving member 51 is a cylindrical body as a whole. Nearly the center of the cylindrical body in the axial direction is a housing portion 51a for receiving the other end portion (round hook) 41b of the tension coil spring 41, and a flange portion 51b is formed in contact with the lower side of the other end portion 41b. Below the flange portion 51b is a cylindrical portion 51c.

A plurality of split grooves 51d (see FIG. 4 (a)) that are long in the axial direction are formed in the radial direction of the cylindrical body in the upper portion of the accommodating portion 51a. A claw portion 51e is formed between the adjacent split grooves 51d on the upper portion of the accommodating portion 51a.
The tip of the claw 51e has an extension 51f extending in the radial direction compared to the diameters of the housing 51a and the cylinder 51c, and the tip of the claw 51e including the extension 51f 51 g is tapered (tapered) and rounded.

  In a state before the spring receiving member 51 is attached to the spring attachment member 43, one end portion (round hook) 41a of the tension coil spring 41 is pressed against the outer peripheral surface 51g from the axial direction. Since the outer peripheral surface 51g is rounded and the split groove 51d is present, the tip of the claw portion 51e contracts toward the center of the diameter, and one end (round hook) 41a slides on the outer peripheral surface 51g. It fits in the accommodating part 51a. Thereafter, due to the elasticity of the spring receiving member 51, the outer peripheral surface 51g returns to the original shape again.

  As described above, the spring receiving member 51 to which the one end (round hook) 41 a is attached is fitted into the outer peripheral surface of the cylindrical spacer 52. Since the spring receiving member 51 and the spacer 52 are made of, for example, a plastic material having a small friction coefficient, the spring receiving member 51 and the spacer 52 freely rotate without friction at the boundary between them. The spacer 52 is overlaid with a washer 53, and a screw (attachment shaft) 54 is inserted through the center hole and the hole of the attachment plate 43b, and tightened with a nut 55 from the back side of the attachment plate 43b.

The above description is a schematic configuration of the spring receiving member 51.
On the other hand, in the spring receiving member 51 shown in FIGS. 3 and 4A, the flange portion 51 b has two flanges 51 b each having an angle of about 120 ° with respect to the axial center of the spring receiving member 51. It is. In two circumferential regions (about 60 ° angle) where the flange 51b does not exist, one claw portion 51e is formed on the upper portion of the accommodating portion 51a. The split groove 51d is formed in a circumferential region that becomes a boundary between the flange 51b and the claw portion 51e described above.
In addition, a locking portion 51h (see FIG. 4A) is formed in a part of the circumferential portion 51a where the flange 51b exists, and the end portion 41a has a round shape with the locking portion 51h interposed therebetween. The start and end of the hook are attached.

In the above description, the spring receiving member 51 is attached to the attachment plate 43b after the one end 41a is attached to the spring receiving member 51. On the other hand, the one end 41a can be attached to the spring receiving member 51 after being attached to the attachment plate 43b.
In this case, one end (round hook) 41a of the tension coil spring 41 is pressed against the outer peripheral surface 51g of the spring receiving member 51 from the axial direction. When the outer peripheral surface 51g is rounded and the one end (round hook) 41a is elastically deformed, the one end (round hook) 41a is expanded in diameter and gets over the outer peripheral surface 51g and fits into the accommodating portion 51a. . One end (round hook) 41a returns to the original diameter again.
The post-mounting method described above is also possible for the spring receiving member 51 attached to the attachment plate 43c. However, when the claw portion 51e is arranged on the side of the horizontal portions 42a and 45a like the spring receiving member 51 attached to the horizontal portions 42a and 45a, it cannot be mounted afterward.

Next, an operation for temporarily fixing the spring mounting member 43 to the fixed base 31 will be described.
As shown in FIG. 2, spring attachment members 42 and 45 of the damper unit 32 are attached in advance to the rear surface of the rear lid 22 at the center in the key arrangement direction. When the lids (the front lid 21 and the rear lid 22) are in the fully open position shown in FIG. 2, the rear end of the rear lid 22 is close to the upper back plate 5, so that the spring mounting member 43 is fixed to the fixing base 31. It is not easy to fix to.
Therefore, the front lid 21 is slightly tilted to the near side, and a gap is formed between the rear end of the rear lid 22 and the upper back plate 5 so that the long hole 31b can be seen and a hand can be inserted.
In this state, the protrusions 43d and 43e of the spring mounting member 43 are hooked and temporarily fixed to the long hole 31b located at the rear end of the keyboard instrument main body 1. Since this temporary fixing work may be simple locking, it can be easily performed even if the long hole 31b is not visible.

The long hole 31b that is the locked portion is not point-symmetric (rotationally symmetric). Accordingly, after the locking portions (the pair of protrusions 43d and 43e) matching the shape of the locked portions are inserted into the locked portions (long holes 31b), they are positioned almost correctly and the springs The attachment member 43 and the fixed base 31 do not move relative to each other.
Therefore, after the temporary fixing, the fixed position (in the area other than the screw insertion holes 43f and 43g and the locking position of the spring mounting member 43) and the fixing position (the screw mounting holes 31c and 31d, the horizontal portion of the fixing base). Is substantially exactly the same, and the relative positions of the two do not shift after temporary fixing.
On the other hand, the locked portion is, for example, one round hole, and even if one pin (locking portion) is inserted and temporarily fixed thereto, the spring mounting member 43 is engaged. There is a degree of freedom to rotate around the stop. Therefore, an extra work for positioning the fixed part to the fixed part is required.

After the temporary fixing shown in FIG. 3 is completed, as shown in FIG. 4A, an operation of fixing the spring mounting member 43 to the fixing base 31 with the screw 56 is performed at the fixing position. In the illustrated example, the operation is performed in the fully open state of the lid, similar to FIG.
A screw 56 can be inserted into the gap between the rear end of the rear lid 22 and the upper back plate 5 and screwed with a screwdriver. The damper unit 32 is connected to the fixed side of the rear lid 22 and the keyboard instrument main body 1. Between the two.
In the above description, the fixing operation of the spring mounting member 43 is performed in the fully open state of the lid. However, in the same manner as the temporary fixing operation, the front lid 21 is slightly tilted toward the front side or for safety. Further, the operation may be performed with the front lid 21 tilted forward (the cover body is fully closed).

The fixed position described above is located in the heel direction from the rear end of the lid in one state of the process of covering the top surface of the keyboard, and in the vicinity of the back of the lid. Therefore, it is easy to attach the spring attachment member 43 to the keyboard accommodating portion. It is even better if the locking position described above is in the same position as the fixing position described above.
Note that fixing the spring mounting member 43 to the fixing base 31 is not necessarily limited to screwing with the screw. For example, a part of the spring mounting member 43 may be press-fitted into a fixing position formed in the horizontal portion 31a, caulked, or fixed with a fitting such as a patch lock.
Further, if the locking portion and the locked portion are structured so as not to be detached once they are engaged, the locking position and the fixing position coincide with each other, and the subsequent fixing work is not necessary.

FIG. 5 is a plan view showing the stretched state of the tension coil springs 41 and 44 when the lid is fully closed and fully opened in the first embodiment shown in FIGS. FIG. 5A is a plan view showing a fully opened state and FIG. 5B is a fully closed state.
In the figure, the same parts as those in FIGS. Reference numeral 61 denotes an inter-element center line.
In the damper unit 32 of this embodiment, the one end portions 41a and 44a of the two tension coil springs 41 and 44 are provided with the spring receiving member 51, the spring mounting members 42 and 45, and the like at the rear rear end portion of the rear lid 22, respectively. It is arranged via.

  As shown in FIG. 5 (b), the lid (front lid 21 and rear lid 22) covers the upper surface of the keyboard portion, as shown in FIG. At the end of closing, the tension coil springs 41 and 44 have the maximum elongation, and thus function as dampers when the lid ends to close in order to accumulate elastic energy commensurate with the release of potential energy due to the vertical movement of the lid. To do. Further, when starting to open the lid, the tension coil springs 41 and 44 are contracted to release the accumulated elastic energy.

In the illustrated specific example, two tension coil springs 41 and 44 are arranged symmetrically with respect to the inter-element center line 61. However, in order to simply function as a damper, the above-described damper unit 32 only needs to be provided with one tension coil spring disposed in the longitudinal direction of the key and extending and contracting.
Hereinafter, a description will be given focusing on one tension coil spring, for example, the tension coil spring 41. The attachment position of the one end 41a and the attachment position of the other end 41b are determined by the moving direction of the rear lid 22 (the longitudinal direction of the key). The tension coil spring 41 is disposed on a crossing oblique straight line with respect to the center line 61 between the elements). In other words, the value of the angle θ of the arrangement direction (coil axis) with respect to the longitudinal direction of the key changes in the entire process in which the cover body covers the upper surface of the keyboard part, but θ = 0 ° does not occur.

In the illustrated example, θ ₁ ≈25 ° in the fully closed state shown in FIG. 5A and θ ₂ ≈65 ° in the fully open state shown in FIG. 5B. In the fully open state, θ ₂ may be 90 °.
When the lid body moves in the longitudinal direction of the key, the angle θ of the direction in which the tension coil spring 41 is disposed with respect to the movement direction of the rear lid 22 changes.
When one end 41a and the other end 41b (more precisely, both spring receiving members 51) of the tension coil spring 41 are re-approaching, θ = 90 °. The closer to θ = 90 °, the smaller the extension of the tension coil spring 41 compared to the amount of change in the movement distance of the lid, and the smaller the biasing force of the tension coil spring 41 proportional to this extension. Also, the component force ratio of the moving direction component of the lid to the urging force is smaller as θ is closer to 90 °. As a result, the biasing force of the tension coil spring 41 applied in the moving direction of the lid is also small.
On the other hand, as θ is closer to 0 °, the extension of the tension coil spring 41 approaches the amount of change in the movement distance. In addition, the component force ratio of the moving direction component of the lid to the urging force becomes approximately 1 as θ approaches 0 °. As a result, the urging force of the tension coil spring 41 applied in the moving direction of the lid increases.

FIG. 6 is a graph qualitatively showing the characteristics when the tension coil spring 41 is disposed obliquely with respect to the relative movement direction of the both end portions 41a and 41b.
In the drawing, the horizontal axis represents the moving distance of the rear lid 22, and the vertical axis represents the biasing force component of the tension coil spring 41 in the moving direction of the rear lid 22.
Reference numeral 71 denotes an apparent spring characteristic when the tension coil spring 41 disposed obliquely with respect to the moving direction of the lid (longitudinal direction of the key) is non-linear.
That is, the apparent spring constant (slope) is smaller in the vicinity of the fully open state corresponding to FIG. 5A than in the vicinity of the fully closed state corresponding to FIG.

Therefore, in the vicinity of the fully opened state of the lid shown in FIG. 5A, when the operator temporarily fixes the spring mounting member 43 to the fixed base 31, the lid moving direction component of the biasing force of the tension coil spring 41 is Get smaller. At that time, it is not necessary to loosen the tension coil spring 41.
Even if the operator pulls the tension coil spring 41, the lid body movement direction component of the urging force is small, so that the lid body does not easily fall backward (back side) of the instrument. As a result, the lid does not get in the way of work, and the finger is not pinched by the lid, so the work becomes easy.
On the other hand, in the vicinity of the fully closed position of the lid shown in FIG. 5 (b), the tension coil spring 41 approaches the biasing force when it is assumed that the tension coil spring 41 is disposed in the direction of movement of the lid, so Even if it arrange | positions to, the damper effect | action of the tension coil spring 41 is not impaired.
Even when the spring mounting member 43 is fixed to the fixing base 31 with screws or the like without temporarily fixing, the same operation and effect can be obtained during the fixing operation.

  Further, when looking at the whole process in which the cover body covers the upper surface of the keyboard part, the extension amount of the tension coil spring 41 is smaller than the movement distance of the cover body. Accordingly, as a comparative example, assuming a tension coil spring disposed in the moving direction of the lid (longitudinal direction of the key), the tension coil spring 41 disposed obliquely or vertically compared to the spring constant of the assumed tension coil spring. The spring constant of is large. Therefore, a spring having a larger spring constant can be used when the tension coil spring is disposed obliquely or vertically.

In addition, the mounting position of the one end portion 41a of the tension coil spring 41 and the mounting position of the other end portion 41b are arranged obliquely or orthogonally to the moving direction of the lid (the coil axis is inclined or orthogonal). Thus, even if the attachment position of the one end portion 41a of the tension coil spring 41 is the rear end portion of the rear lid 22, the tension coil spring 41 that requires a predetermined length can be disposed.
On the other hand, when one end portion of the tension coil spring assumed as the comparative example is attached in the vicinity of the front end of the rear cover 22, when the rear cover 22 moves to the front side, it exists on the front side of the keyboard instrument main body portion 1. There is a problem of interference with the upper part of the keyboard unit 9 and the operation panel 10.
On the other hand, in the vicinity of the rear end of the electronic keyboard instrument 1 located on the back side of the keyboard, it is easy to configure so that there is no internal structure that interferes with the tension coil spring 41 in the key arrangement direction. it can.

  In the above description, one tension coil spring 41 has been described. When the damper unit 32 includes only the tension coil spring 41 (first element) that is obliquely or vertically arranged in one direction, the biasing force component of the spring is in a direction perpendicular to the moving direction of the lid (key arrangement direction). Works. Therefore, there is a possibility that the lid body does not move in the longitudinal direction of the key but bends in the key arrangement direction. Therefore, a member that regulates the moving direction is required. Further, in the specific example shown in FIG. 1, when the protruding body 26 a comes into contact with the groove surface of the guide groove 27 a or the L-shaped member 26 comes into contact with the guide member 27, the movement of the lid body causes sliding friction. May be less smooth.

Accordingly, in the illustrated specific example, a pair of tension coil springs 44 having the same characteristics as the tension coil springs 41 are arranged as second elements (elements) so as to be line-symmetric in the key arrangement direction. The two are coupled by a single spring mounting member 43. As a result, the spring force in the key arrangement direction is canceled out.
Here, the line symmetry means that the elements are arranged in line symmetry with respect to the inter-element center line 61 in FIG.

In the illustrated example, two separate (two elements) tension coil springs 41 and 44 are used. It may replace with this and may use the tension coil spring of 2 elements (element) formed using one wire. In this case, the midpoint of one spring material may be used as the locking point.
This locking point (locking portion) is attached to the spring mounting member 43 using one spring receiving member. As a result, the number of spring receiving members can be reduced to one, and the attaching process to the spring receiving members can be saved once.
However, even if two separate and independent tension coil springs 41 and 44 as shown in the figure are used, if the common spring mounting member 43 is used, it can be attached to the fixing base 31 in one step, so that the operation is easy. Become.
Although the work of attaching the ends of the two separate and independent tension coil springs 41 and 44 to the common spring mounting member 43 increases, the separate and independent tension coil springs 41 and 44 are attached to the spring mounting member 43 one by one in advance. This work is easy because it only needs to be done.

The illustrated damper unit 32 uses two-element tensile coil springs 41 and 44 arranged in line symmetry. However, if the biasing force component in the direction orthogonal to the moving direction of the lid (key arrangement direction) cancels out or decreases, it does not have to be line symmetric, and more than 3 elements (even numbers) Or a plurality of tension coil springs having different shapes and spring characteristics.
A specific arrangement form is illustrated. The damper unit 32 shown in the figure can be referred to as a “C” shape of katakana and a “V” shape of alphabet.
Moreover, when it is 4 elements (element), it can be said that it is an alphabet "W" shape.

In the illustrated example, the spring mounting member 43 common to a plurality of elements is used for mounting to the rear end portion of the keyboard instrument main body 1. However, conversely, a common spring mounting member 43 is used for mounting to the rear cover 22, and the individual spring mounting members 42, shown in FIG. 4 are used for mounting to the rear end of the keyboard instrument body 1. 45 may be used.
In this case, the arrangement of the above-mentioned “C” (“V”) shape and “W” shape is an inverted arrangement.

  In the illustrated example, two elements (tensile coil springs 41 and 44) are coupled by one spring mounting member 43. However, it is not always necessary to temporarily fix a plurality of elements to a fixed portion with one spring mounting member. There is no need to fix. Each element may be temporarily fixed and fixed to a common or individual fixing portion by using a dedicated spring mounting member. Depending on the mounting position of each element, a common spring mounting member or a dedicated spring mounting member may be used. The damper units 32 do not necessarily need to be centrally arranged at the center in the key arrangement direction, and may be arranged at one end in the key arrangement direction, or may be distributed at a plurality of positions.

  In the above description, when the lid body is closed to the near side, the keyboard instrument is structured to close by the weight of the lid body, and the damper unit includes the lid body (front lid 21 and rear lid 22). In the process of covering the upper surface of the part, when the lid is closed to the near side and the keyboard part is fully closed, by storing elastic energy commensurate with the release of potential energy due to the vertical movement of the lid, It functions as a damper when the lid is closed to the near side, and acts to release the accumulated elastic energy when the lid starts to open.

On the other hand, in the fully open state of the lid shown in FIGS. 1 and 2, the front lid 21 is inclined rearward. In this case, when the lid has been opened, the present invention can be applied to a keyboard instrument in which the lid suddenly falls backward due to the weight of the lid, particularly a keyboard instrument having a large backward tilt angle. It is.
In this case, when the damper unit finishes opening the lids (the front lid 21 and the rear lid 22) to the back side and fully opens the keyboard surface, it corresponds to the release of potential energy due to the vertical movement of the lid. By accumulating the elastic energy, it functions as a damper when the lid is opened rearward, and acts to release the accumulated elastic energy when the lid starts to close.

FIG. 7 is a cross-sectional view for explaining a second embodiment of the present invention. FIG. 3 is a cross-sectional view as seen from the right side to the left side in the center of the key arrangement direction, similarly to FIGS. FIG. 7A shows the lid (front lid 21 and rear lid 22) fully opened, and FIG. 7B shows the lid fully closed.
In the figure, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals.
In this embodiment, a moving region of the tension coil spring 81 is ensured between the end portion of the keyboard portion (white key 7 and black key 8) and the side plate 4 on each of the left and right sides of the keyboard instrument body portion (keyboard housing portion) 1. To do. (In this figure, the tension coil spring in the left moving region is visible). In this moving region, the tension coil spring 81 expands and contracts while avoiding interference with other components.
When viewed from the front side, this moving region is a region of the left and right time tree front portions 82 and the time tree rear portion 83 integral therewith.

The fixed base 84 is installed on the side plate 4 side in the moving region described above, and in front of the horizontal portion 84a of the fixed base 84, as shown in FIG. 7B, the rear end of the rear lid 22 and the upper back plate 5 are connected. A long hole (locking portion) 84b and a screw mounting hole 84c are formed at positions where temporary fixing and screw mounting can be performed from the gap.
The spring mounting member 85 is, for example, an L-shaped member, and a projection (locked portion) 85a and a screw insertion hole 85b are formed on the horizontal plate. Further, the spring receiving member 51 is supported on the vertical plate with the shaft as the key arrangement direction.

  Reference numeral 86 denotes an arm, which has the same structure as the arm 24 shown in FIG. 1 and is attached to the left and right ends of the front lid 21 in the same manner. However, unlike the arm 24, the arm 86 is extended to the opposite side of the rotation fulcrum portion 86d, and the arm extension portion 86e serves as a spring mounting portion, and the spring receiving member 51 is rotatably supported by the spring mounting portion. Has been. It can be said that this spring mounting portion is provided at the rear end portion of the front lid 21 constituting the lid.

One end of the tension coil spring 81 is attached to the arm extending portion 86e in advance, and the other end is attached to the spring attachment member 85 in advance.
When the lid shown in FIG. 7B is in the fully closed state, the rear end of the rear lid 22 is farthest from the upper back plate 5. At this time, the protruding portion (locked portion) 85a of the spring mounting member 85 is a long hole (locking portion) 84b in the horizontal portion (fixed portion) 84a located at the rear end on the back side of the keyboard instrument main body portion 1. Temporarily fix to. After the temporary fixing is completed, an operation of fixing the spring mounting member 85 to the fixing base 84 with the screw 87 is performed.

Accordingly, the tension coil spring 81 is stretched between the arm extending portion (spring mounting portion) 86e and the spring mounting member 85. The arm extension portion (spring attachment portion) 86e is located on the keyboard side of the spring attachment member 85, and the spring attachment portion 86b is located on the side plate 4 side. Is disposed obliquely or orthogonally to the longitudinal direction).
As a result, in the state shown in FIG. 8 (b), when the spring mounting member 85 is temporarily fixed to the fixing base 84 and when it is continuously fixed, the biasing force component in the moving direction of the lid (longitudinal direction of the key) Is small, the attachment work of the tension coil spring 81 is facilitated.
Generally, in an electronic keyboard instrument, one or a plurality of performance operators may be arranged on the left time signature front portion 82. In this case, there is room in the left area. Therefore, only the left side may be the arm 81 and the above-described damper mechanism may be installed, and the right side may be the arm 24 shown in FIG.
In the first embodiment, when the guide member 27 for guiding the rear cover 22 to move in the longitudinal direction of the key as shown in FIG. 1 is installed, the projection is prevented so as not to interfere with the movement of the tension coil spring 81. It is necessary to design a place where the body 26a and the guide member 27 are installed.

FIG. 8 is a plan view for explaining a third embodiment of the present invention. FIG. 8A is a plan view showing the expansion and contraction state of the tension coil spring when the lid is fully opened, FIG. 8B is when the lid is intermediately opened, and FIG. 8C is when the lid is fully closed. It is.
This embodiment is based on the configuration of the first embodiment described with reference to FIGS. The tension coil spring (tensile force generating elastic element) of the damper unit 32 is shown in FIG. 8C when the lid (front lid 21, rear lid 22) is closed to the front side and the keyboard is fully closed. 8 and FIG. 8 (a), the elastic energy corresponding to the release of potential energy due to the vertical movement of the lid body is accumulated at any time when the lid body is opened to the back side and fully opened. Therefore, it functions as a damper.

In the figure, the same parts as those in FIGS. Reference numeral 91 denotes a fixed base, and the overall shape and the mounting position on the upper back plate 5 and the shelf board 2 are the same as those of the fixed base 31 shown in FIG. The horizontal portion (fixed portion) 91a of the fixed base 91 is located on the back side of the keyboard portion, but the positions of the long holes (locking portions) 91b and the screw mounting holes 91c and 91d in the horizontal portion 91a (the longitudinal direction of the key). Position) is moved closer to the front side (front of the instrument) than the corresponding portion of the fixed base 31. Accordingly, the positions of the attachment portions 91i and 91j are also moved.
The tension coil springs 92 and 93 correspond to the tension coil springs 41 and 44 shown in FIG. 2, but their shapes, dimensions, and characteristics do not necessarily match.

In this embodiment, when the lids (the front lid 21 and the rear lid 22) shown in FIG. 8B are in an intermediate open state, both ends of the tension coil spring 92 and both ends of the tension coil spring 93 are covered with the lid. They are arranged in a direction (key arrangement direction) orthogonal to the body movement direction (direction of the center line 61 between elements).
Here, when the lids (the front lid 21 and the rear lid 22) are in the intermediate open state, the front lid 21 stands up vertically. Therefore, the potential energy due to the vertical movement of the lid is the largest.
In this state, even if the tension coil springs 92 and 93 themselves extend and have an urging force, an angle θ formed by a line (coil shaft) connecting both ends of the tension coil spring 92 (93) with the lid moving direction is 90. Therefore, the lid moving direction component of this urging force is zero.

On the other hand, when the lid shown in FIG. 8C is fully closed, the spring mounting members 42 and 45 disposed on the back surface of the rear lid 22 (the rear end portion of the lid) are attached to the fixing base 91. It moves to the near side of the spring mounting member 43. Accordingly, since θ ₅ is less than 90 °, the extension state of the tension coil springs 92 and 93 is the same as that when the lid body is fully closed as shown in FIG. 5B, and therefore the lid body is fully closed. In doing so, as in the first embodiment described with reference to FIGS. 1 to 6, the tension coil springs 92 and 93 perform a damper function.

On the other hand, when the lid is fully opened as shown in FIG. 8A, the spring attachment members 42 and 45 are moved to the rear of the instrument from the spring attachment member 43 attached to the fixed base 91. As a result, when the tension coil springs 92 and 93 are based on the state shown in FIG. 8B, the tension coil springs 92 and 93 are in an extended state, and a line (coil axis) connecting both ends of the tension coil spring 92 (93) is present. The angle θ ₃ formed with the lid moving direction is greater than 90 °. Therefore, the lid moving direction component of this urging force works to return the lid to the state shown in FIG. As a result, it functions as a damper even when the lid is fully opened.

In this embodiment, in the state from the intermediate open state shown in FIG. 8 (b) to the fully closed state shown in FIG. 8 (c), the protruding portion (locked portion) 43d of the spring mounting member 43 is provided. , 43e are temporarily fixed by engaging with a long hole (engagement portion) 91b in the horizontal portion 91a of the fixing base 91.
After the temporary fixing, the screw insertion holes (fixed positions) 43f and 43g can be seen from above and the screws 56 can be inserted, and the screws 56 are used to attach the spring mounting member 43 to the screw mounting holes (fixed positions) 91c, Work to fix to 91d.
When temporarily fixing and fixing, since the biasing force component in the moving direction of the lid (longitudinal direction of the key) is small, the attaching work of the tension coil springs 92 and 93 becomes easy.

In the above description, the intermediate open state illustrated in FIG. 8B has been described as the state in which the front lid 21 is vertically raised. However, in an intermediate open state that does not coincide with the state in which the front lid 21 stands up vertically, both ends of the tension coil springs 92 and 93 as shown in FIG. It may be arranged in the arrangement direction.
Further, when the attachment position of the spring attachment member 43 is attached to a position shifted further forward of the musical instrument, such as point P shown in FIG. 8C, the entire stroke from the fully closed state to the fully open state is achieved. , The angle θ formed by the line connecting the both ends of the tension coil spring 92 (93) with the lid moving direction is always greater than 90 °.
Accordingly, as in the second embodiment described with reference to FIG. 7, the tension coil springs 92 and 93 are made to function as dampers only when the lid is completely opened to the back side. be able to.

The third embodiment described with reference to FIG. 8 is based on the configuration of the first embodiment described with reference to FIGS. Similarly, various modifications are possible.
In each of the above-described embodiments, the tension coil spring is used as the tensile force generating elastic element. However, any device that generates a tensile force may be used. For example, a bellows spring having a shape obtained by bending a long metal thin plate into a zigzag shape (a shape of “K” in Hiragana, the shape representing the tension coil springs 92 and 93 in FIG. 8) may be used. Further, the elastic element is not limited to the metal spring but may be made of synthetic resin or rubber.
In any of the embodiments described above, a damper mechanism such as a conventional one-way clutch mechanism may be provided at the rotation fulcrum.

In the above description, the lid is applied to a structure having a front lid 21 that rotates and a rear lid 22 that is hinged at the front end of the front lid 21 and moves substantially linearly in the longitudinal direction of the key. did.
However, there is no lid having a different structure, for example, there is no equivalent to the front lid 21, which corresponds to the rear lid 22, and moves substantially linearly in the longitudinal direction of the key. You may apply to a cover body which discharge | releases a positional energy by moving up and down when it completes opening to the side. Alternatively, there is nothing corresponding to the rear lid 22, which corresponds to the front lid 21, and the damper unit 32 may be attached near the rear end of the upper surface (front side) of the front lid 21. In this case, what is necessary is just to add the member which covers so that the damper unit 32 cannot be seen from the outside.

It is the 1st sectional view explaining a 1st embodiment of the invention in this application. It is sectional drawing which looked at the left side from the right side in the key arrangement direction center part shown by arrow AA in Fig.5 (a). It is 2nd sectional drawing explaining 1st Embodiment of this invention. FIG. 3 is a cross-sectional view of the key from the right side to the left side in the center of the arrangement direction of the keys as in FIG. It is an expansion perspective view which shows the operation | work which temporarily fixes the spring attachment member shown in FIG. 2 to a fixed base. It is explanatory drawing which shows the operation | work which fixes the spring attachment member shown in FIG. 2 to the horizontal part of a fixed base. 4A is a partially enlarged view of the circular portion shown in FIG. 2, and FIG. 4B is a cross-sectional view for explaining the basic structure of the spring receiving member. In 1st Embodiment shown in FIGS. 1-4, it is a top view which shows the expansion-contraction state of a tension coil spring in the time of a fully closed and a fully open state of a cover body. It is a graph which shows the characteristic at the time of arrange | positioning diagonally with respect to the relative moving direction of the both ends of a tension coil spring qualitatively. It is sectional drawing explaining the 2nd Embodiment of this invention. FIG. 3 is a cross-sectional view as seen from the right side to the left side in the center of the key arrangement direction, similarly to FIGS. 1 and 2. It is a top view explaining 3rd Embodiment of this invention. FIG. 8A is a plan view showing the expansion and contraction state of the tension coil spring when the lid is fully opened, FIG. 8B is when the lid is intermediately opened, and FIG. 8C is when the lid is fully closed. It is.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Keyboard instrument main-body part (keyboard accommodating part), 2 ... Shelf board, 3 ... Mouth stick, 4 ... Side board, 4a ... Groove, 5 ... Upper back board, 6 ... Upper front unit, Keyboard part (7 ... White key, 8 ... black key), 9 ... keyboard unit, 10 ... operation panel, 11 ... front of the beat tree, 12 ... rear of the beat tree, 13 ... input / output terminal box, 14 ... lower plate fixing block,
Lid (21 ... front lid, 22 ... rear lid), 21a ... front wall, 21b ... music stand, 23 ... hinge, 24 ... arm, 24a ... mounting plate, 24b ... mounting plate extension, 24c ... rotating plate 24d: Rotating fulcrum part, 25 ... Rotating support part, 26 ... L-shaped member, 26a ... Projection body, 27 ... Guide member, 27a ... Guide groove, 28 ... L-shaped member, 29 ... Buffering member,
31 ... fixed base, 31a ... horizontal part (fixed part), 31b ... long hole (locking part), 31c, 31d ... screw mounting hole, 31e ... front leg, 31f ... mounting part, 31g, 31h ... rear leg, 31i, 31j, 31k ... mounting portion, 32 ... damper unit (one or more tensile force generating elastic elements), 33 ... spacer, 41, 44 ... tension coil spring (tensile force generating elastic element), 41a, 44a ... one end, 41b, 44b ... the other end, 42, 45 ... spring mounting member, 42a, 45a ... horizontal portion, 42b, 42c ... mounting plate, 42d, 42e, 45d, 45e ... vertical portion, 43 ... spring mounting member (elastic element mounting member) , 43a ... horizontal portion, 43b, 43c ... mounting plate, 43d, 43e ... projection (locked portion), 43f, 43g ... screw insertion hole, 43h, 43i ... vertical portion, 51 ... spring receiving member, 51a ... accommodating Part, DESCRIPTION OF SYMBOLS 1b ... Flange part, 51 ... c cylindrical part, 51d ... Split groove, 51e ... Claw part, 51f ... Extension part, 51g ... End surface, 51h ... Locking part, 52 ... Spacer, 53 ... Washer, 54 ... Screw, 55 ... nuts, 56 ... screws,
61 ... center line between elements, 71 ... spring characteristics when using a tension coil spring 41 disposed obliquely with respect to the moving direction of the lid,
DESCRIPTION OF SYMBOLS 81 ... Tension coil spring, 82 ... Beating tree front part, 83 ... Beating tree rear part, 84 ... Fixing stand, 84a ... Horizontal part (fixing part), 84b ... Long hole (locking part), 84c ... Screw mounting hole, 85 ... Spring mounting 85a ... Projection (locked part), 85b ... Screw insertion hole, 86 ... Arm, 86a ... Mounting plate, 86b ... Mounting plate extension, 86c ... Rotating plate, 86d ... Rotating fulcrum, 86e ... arm extension part,
91 ... fixed base, 91a ... horizontal portion (fixed portion), 91b ... long hole (locking portion), 91c, 91d ... screw mounting hole, 91f, 91i, 91j ... mounting portion, 92, 93 ... tensile coil spring

Claims (4)

A lid opening / closing device for a keyboard instrument having a keyboard part, a lid for covering the upper surface of the keyboard part, and a keyboard accommodating part for accommodating the keyboard part,
In the inside of the keyboard housing portion, a fixing portion is fixed to the keyboard housing portion and located on the back side of the keyboard portion,
And several of the tensile force-generating elastic element,
Has one or more elastic elements attached member for attaching the tensile force-generating resilient element of said plurality of prior Symbol solid tough,
Each of the tensile force generating elastic elements has one end disposed at the rear end of the lid body and the other end disposed at the elastic element mounting member, and / or when the lid body is closed to the near side, and / or When the lid is finished to open to the back side, by accumulating elastic energy corresponding to the release of potential energy due to the vertical movement of the lid, when the lid is closed to the front side, and / or It functions as a damper when opening the lid to the back side,
One end and the other end of each tensile force generating elastic element are disposed obliquely or orthogonally to the moving direction of the lid , and
The plurality of tensile force generating elastic elements are arranged in parallel so that components of the biasing force orthogonal to the moving direction of the lid body substantially cancel each other .
A lid opening / closing device for a keyboard instrument characterized by the above. The plurality of tensile force generating elastic elements are arranged in line symmetry with respect to the moving direction of the lid,
The lid opening / closing device for a keyboard instrument according to claim 1 . The plurality of tensile force generating elastic elements are a plurality of independent and independent tensile force generating elastic elements,
At least one of the one or more elastic element attachment members is attached with at least two other ends of the plurality of independent and independent tensile force generation elastic elements.
The lid opening / closing device for a keyboard instrument according to claim 1 or 2 , The locking portion is formed before Symbol solid tough,
The elastic element mounting member has a locked portion,
It said elastic element attachment member by該被locking portion is engaged with the engaging portion formed on the fixing portion Ru is temporarily fixed to the fixed portion,
The lid opening / closing device for a keyboard instrument according to any one of claims 1 to 3 , wherein the lid opening / closing device for a keyboard instrument is provided.

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