WO2017126336A1 - Instrument pedal device - Google Patents

Abstract

Provided is an instrument pedal device that can be easily produced. According to the present invention, a pedal (30) is rotatably supported on a base part (20) by a first shaft (11). A rotation part (40) that is rotatably supported on the base part (20) by a second shaft (12) rotates in accordance with rotation of the pedal (30). The pedal (30) rotates around the first shaft (11) and can rotate from an initial position to a lowermost position. Urging force that is for making the pedal (30), as rotated from the initial position, return to the initial position is applied by a spring (60). The base part (20) comprises a bottom-surface plate (22) and a pair of side-surface plates (23) that rise from side edges (22c) of the bottom-surface plate (22). The bottom-surface plate (22) and the pair of side-surface plates (23) are formed from single plates.

Description

Pedal device for musical instruments

The present invention relates to a pedal device for musical instruments. In particular, the present invention relates to a musical instrument pedal device that can be easily manufactured.

2. Description of the Related Art Pedal devices for musical instruments used to play acoustic percussion instruments such as bass drums and hi-hat cymbals, electronic musical instruments that simulate acoustic percussion instruments, or to practice performance are known. As a pedal device for a musical instrument, for example, a pair of standing portions are erected on a long plate-shaped grounding plate serving as a base, and a rotating body that rotates in response to depression of the pedal is a pair of standing portions. Is pivotally supported (Patent Document 1).

JP 2014-81501 A

However, in Patent Document 1, in order to provide an upright portion on the ground plate, it is necessary to weld the separately prepared ground plate and the upright portion to each other or to connect each other with a fixture such as a bolt.

The present invention was made to solve the above-mentioned problems. An object of this invention is to provide the pedal apparatus for musical instruments which can be manufactured easily.

In order to achieve this object, a musical instrument pedal device according to the present invention includes a base portion placed on a floor surface and a pedal rotatably supported on the base portion with a first shaft as a rotatable range from an initial position to a lowest position. A rotating portion that is rotatably supported by the base by a second shaft parallel to the first shaft and rotates according to the rotation of the pedal, and returns the pedal rotated from the initial position to the initial position. An urging member for applying an urging force to the base plate, the base portion extending from the first end toward the second end, and a side plate extending from the first end to the second end, and the side edge on the second end side of the bottom plate. The bottom plate and the pair of side plates are formed of a single plate material, and the second shaft is spanned between the pair of side plates.

According to the musical instrument pedal device of the first aspect, when the performer depresses (operates) the pedal, the pedal rotates around the first axis within a rotatable range from the initial position to the lowest position. Since the bottom plate and the pair of side plates are formed from a single plate material, the bottom plate and the pair of side plates can be formed by bending one plate material. Since the second shaft is stretched over the pair of side plates, the pair of side plates can be made difficult to fall in the opposing direction. As a result, the musical instrument pedal device has an effect of facilitating the manufacture of the musical instrument pedal device while ensuring the strength and rigidity of the pair of side plates.

According to the musical instrument pedal device of the second aspect, the pair of side plates are connected to each other by the second shaft, and the second shaft is fixed to the pair of side plates. The rotating part slides with respect to the second axis. Thereby, in addition to the effect of Claim 1, the pedal apparatus for musical instruments is the junction part of a 2nd axis | shaft and a pair of side plate with respect to the force which acts on a 2nd axis | shaft and a pair of side plate via a rotation part. In addition, the strength and rigidity of the pair of side plates can be improved.

Also, since the rotating part slides with respect to the second shaft, the musical instrument pedal device has an effect that the rotating part can be downsized as compared with the case where a bearing is provided between the rotating part and the second shaft.

According to the musical instrument pedal device of the third aspect, the rib rising from the side edge of the bottom plate of the base is formed integrally with the side plate. As a result, the pedal device for musical instruments has the effect of improving the strength and rigidity of the bottom plate while facilitating the formation of ribs by bending one plate material in addition to the effect of the first or second aspect.

According to the pedal device for a musical instrument according to claim 4, the notch hole is formed in the pair of side plates upward from the side edge of the bottom plate. A leg portion is formed on the bottom plate by projecting outward from the side edge of the bottom plate at a position corresponding to the notch hole. Thereby, the pedal apparatus for musical instruments can be made difficult to fall down.

The dimension of the leg is formed below the dimension of the notch hole. Therefore, a leg part can be easily formed by bending one sheet material except the inside of a notch hole, and forming a side plate. As a result, the musical instrument pedal apparatus has the effect of ensuring the stability of the musical instrument pedal apparatus by the leg portions that are easy to form in addition to the effects of any one of the first to third aspects.

According to the musical instrument pedal device of the fifth aspect, the rotating portion includes the attachment portion whose end portion projects outwardly from between the facing portions of the pair of side plates. The urging member connects the base and the mounting portion outside the space between the pair of side plates facing each other. Therefore, the dimension of the pair of side plates in the facing direction can be suppressed as compared with the case where the biasing member is provided between the pair of side plates facing each other. As a result, the pedal device for musical instruments has the effect of reducing the size of the pedal device for musical instruments in addition to the effect of any one of claims 1 to 4.

It is a perspective view of the pedal device for musical instruments in a 1st embodiment of the present invention. It is sectional drawing of the pedal apparatus for musical instruments which showed the initial position of the pedal. It is a top view of the flame | frame of the pedal apparatus for musical instruments. It is a perspective view of a rotation part. It is sectional drawing of the pedal apparatus for musical instruments which showed the moment when the sensor part and the pedal contacted. It is sectional drawing of the pedal apparatus for musical instruments which showed the lowest position of the pedal. 6 is a graph schematically showing pedal angle-pedal reaction force. It is a side view of the pedal device for musical instruments with which the hi-hat stand in a 2nd embodiment was equipped. It is the perspective view which expanded a part of hi-hat stand. It is a side view of the pedal device for musical instruments. It is sectional drawing of the pedal apparatus for musical instruments. It is sectional drawing of the pedal apparatus for musical instruments in 3rd Embodiment. It is the model of the pedal apparatus for musical instruments which showed the initial position in 4th Embodiment. It is the schematic diagram of the pedal apparatus for musical instruments seen from the arrow XIV direction of FIG. It is the model of the pedal apparatus for musical instruments which showed the lowest position.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. First, a schematic configuration of a musical instrument pedal device (hereinafter referred to as a “pedal device”) 10 according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view of a pedal device 10 according to the first embodiment of the present invention. FIG. 2 is a sectional view of the pedal device 10 showing the initial position of the pedal 30. The right side of the drawing in FIG. 2 will be described as the front of the pedal device 10. The front side of the paper in FIG. 2 will be described as the left side of the pedal device 10. The description will be made assuming that the upper side of the sheet of FIG. The initial position of the pedal 30 is the position of the pedal 30 in a state where the performer does not depress (operate) the pedal 30.

As shown in FIGS. 1 and 2, the pedal device 10 is a device for playing an electronic musical instrument that simulates a percussion instrument such as a bass drum whose hitting surface is hit by the operation of the pedal. The pedal device 10 includes a base portion 20, a pedal 30, a rotating portion 40, a connecting portion 50, a spring 60 (biasing member), and a sensor portion 70. The pedal 30 is rotatably supported on the base 20 by the first shaft 11. The rotating part 40 is rotatably supported by the base part 20 on the second shaft 12. The connecting portion 50 is rotatably supported on the pedal 30 by the third shaft 13. The connecting portion 50 is rotatably supported on the rotating portion 40 by the fourth shaft 14.

The first shaft 11, the second shaft 12, the third shaft 13, and the fourth shaft 14 are provided in parallel to each other and extend horizontally when the pedal device 10 is installed on the floor surface. These axes are located in the order of the second axis 12, the fourth axis 14, the third axis 13, and the first axis 11 from above. The fourth shaft 14 is positioned closer to the first shaft 11 than the plane including the second shaft 12 and the third shaft 13 when the pedal 30 is in the initial position. Thereby, compared with the case where the 4th axis | shaft 14 is located in the other side of the 1st axis | shaft 11 rather than the plane containing the 2nd axis | shaft 12 and the 3rd axis | shaft 13, the pedal apparatus 10 can be reduced in size.

The base 20 is a member that is a foundation of the pedal device 10. The base portion 20 is formed by attaching a front grounding portion 25 and a rear grounding portion 26 to a plate-like frame 21. The base 20 is placed on the floor surface with the front grounding portion 25 and the rear grounding portion 26 grounding to the floor surface.

The frame 21 is composed of a single metal plate. The frame 21 includes a bottom plate 22 (bottom surface portion), a side plate 23, and a rib 24. The bottom plate 22 has a side edge 22c extending from a first end 22a that is an end portion on the front side (right side of FIG. 2) toward a second end 22b that is an end portion on the rear side (left side of FIG. 2).

The bottom plate 22 is a rectangular part constituting the bottom surface of the base 20. The side plates 23 are a pair of portions that respectively constitute the side surfaces of the base portion 20. The side plate 23 rises from the side edge 22c of the bottom plate 22 on the second end 22b side. The rib 24 is a part for ensuring the rigidity of the bottom plate 22 and is provided from the side plate 23 to the first end 22a. The rib 24 rises from the side edge 22 c and is formed integrally with the side plate 23. Since a part of the pedal 30 projects outward from the side edge 22c, the height of the rib 24 is set so as not to contact the lowermost pedal 30 (see FIG. 6).

Next, a method for manufacturing the base 20 will be described with reference to FIG. FIG. 3 is a plan view of the frame 21 of the pedal device 10. In FIG. 3, the side plate 23 before bending is illustrated by a two-dot chain line. As shown in FIG. 3, first, one plate material having a shape in which a portion corresponding to the side plate 23 indicated by a two-dot chain line projects from the side edge 22 c of the bottom plate 22 is prepared. Further, the front mounting portion 22 d protrudes from the first end 22 a of the bottom plate 22 of the one plate material.

In a portion corresponding to the side plate 23 of the one plate material, a cutout hole 23a is formed by cutting out from the side edge 22c. In addition, the notch hole 23a is formed so that the leg part 22e protruding from the side edge 22c of the bottom plate 22 is left inside the notch hole 23a. Further, a shaft hole 23b, a guide hole 23c, a first mounting hole 23d, a second mounting hole 23e, and an output terminal hole 23f are formed in a portion corresponding to the side plate 23 of one plate material. In addition, it is possible to perform simultaneously the process of forming the external shape of one board | plate material, and the process of forming each hole 23a, 23b, 23c, 23d, 23e, and 23f.

Then, a pair of side plates 23 and ribs 24 are formed by bending one plate member at a substantially right angle at the side edge 22c, and the frame 21 is formed. In this way, since the frame 21 (base 20) can be easily formed, the pedal device 10 can be easily manufactured. Finally, the front grounding portion 25 (see FIG. 2) is attached to the front attachment portion 22d of the frame 21, and the rear grounding portion 26 (see FIG. 2) is attached to the leg portion 22e to form the base portion 20.

Further, when bending one plate material, the leg portion 22e can be easily formed by bending the one plate material except the inside of the notch hole 23a to form the side plate 23. Further, in a state before bending, a notch hole 23a is provided so that a predetermined gap is formed between the side plate 23 and the leg portion 22e. That is, the dimension of the leg portion 22e is set to be less than the dimension of the notch hole 23a. Thereby, the side plate 23 and the leg portion 22e can be easily separated when bending. In addition, it is also possible to set the dimension of the leg part 22e and the dimension of the notch hole 23a substantially equal, without providing a clearance gap between the side plate 23 and the leg part 22e in the state before bending.

Next, the detailed configuration of the pedal device 10 will be described with reference to FIGS. 1 to 3. The bottom plate 22 has leg portions 22e projecting outward in the left-right direction from a side edge 22c at a position corresponding to the notch hole 23a. The dimension of the leg part 22e is formed below the dimension of the notch hole 23a. Since the leg portion 22e protrudes from the side edge 22c to the outside in the left-right direction, the pedal device 10 can be hardly tilted, and the stability of the pedal device 10 can be ensured.

The pair of side plates 23 are each provided with a notch hole 23a above the side edge 22c of the bottom plate 22. Each of the pair of side plates 23 penetrates the upper end (the end portion away from the bottom plate 22) and is provided with a shaft hole 23b. Each of the pair of side plates 23 is provided with a guide hole 23c extending in the circumferential direction around the shaft hole 23b. The pair of side plates 23 are provided with an output terminal hole 23f for exposing the output terminal 77 of the sensor unit 70 on one side.

The first attachment portion 27 is attached to one of the first attachment hole 23d and the second attachment hole 23e. A spring 60 is attached to the first attachment portion 27. The pedal 30 at the initial position is set closer to the bottom plate 22 when the first attachment portion 27 is attached to the second attachment hole 23e than when the first attachment portion 27 is attached to the first attachment hole 23d. In the present embodiment, the first attachment portion 27 is attached to the first attachment hole 23d.

The second shaft 12 is stretched over the pair of side plates 23 through the shaft hole 23b. As a result, the pair of side plates 23 can hardly fall down in the opposing direction, so that the strength and rigidity of the pair of side plates 23 can be ensured.

The second shaft 12 includes a pipe 12a and a bolt 12b. The pipe 12 a is a metal member having a length equivalent to the interval between the pair of side plates 23. The outer diameter of the pipe 12a is formed larger than the diameter of the shaft hole 23b. The bolt 12b is a member inserted into the shaft hole 23b and the pipe 12a. As a result, the facing distance on the upper end side (near the second shaft 12) of the pair of side plates 23 is determined by the length of the pipe 12a.

The pipe 12a is arranged between the pair of side plates 23 so that the axis of the pipe 12a is aligned with the axis of the shaft hole 23b. In this state, the bolt 12b is inserted into the shaft hole 23b and the pipe 12a, and a nut (not shown) is attached to the bolt 12b. Accordingly, the pair of side plates 23 are connected to each other, and the second shaft 12 is fixed to the pair of side plates 23. As a result, with respect to the force acting on the second shaft 12 and the pair of side plates 23 via the rotating portion 40 when the pedal 30 is stepped on, the joint portion or the pair of sides of the second shaft 12 and the pair of side plates 23 The strength and rigidity of the face plate 23 can be improved.

The front grounding portion 25 is a member that receives a load on the front side of the pedal device 10 and a player's heel is placed thereon. The front grounding portion 25 supports the first shaft 11 via a plain bearing (not shown). As for the front grounding part 25, the part which earth | grounds to a floor surface is the rubber foot 25a.

The rear grounding portion 26 is a rubber member that receives the load on the rear side of the pedal device 10 and covers the leg portion 22e. The rear grounding portion 26 is inserted from the laterally outer side of the leg portion 22e, and the rear grounding portion 26 is inserted into the leg portion 22e. In this state, the rear grounding portion 26 is fixed to the leg portion 22e by attaching bolts 28 penetrating the leg portion 22e and the rear grounding portion 26 in the vertical direction. By the rubber feet 25a of the front grounding portion 25 and the rubber rear grounding portion 26, vibration and impact transmitted from the pedal device 10 to the floor surface can be reduced.

The pedal 30 is a member that rotates around the first axis 11 when the performer's foot is placed on the front side and the performer depresses the pedal 30. The pedal 30 is formed so as to extend in a long plate shape from the first end 31 toward the second end 32. The pedal 30 has the first shaft 11 fixed to the first end 31 side and the third shaft 13 fixed to the second end 32 side.

The pedal 30 includes a restriction portion 33 and a bolt hole 34. The restricting portion 33 is a portion that restricts the foot from touching the rotating portion 40 or the like by applying the toe of the performer. The bolt hole 34 is provided closer to the second end 32 than the third shaft 13. Bolts 36 that pass through three plate-like weights 35 are fastened to the bolt holes 34. Thereby, the weight 35 is attached to the second end 32 side of the pedal 30. Since the inertial force when the pedal 30 is depressed by the weight 35 can be increased, the operational feeling of the pedal 30 can be improved. Note that the number and shape of the weights 35 can be changed as appropriate, and the operational feeling can be changed according to the total weight of the weights 35.

Next, the rotating unit 40 will be described with reference to FIG. FIG. 4 is a perspective view of the rotating unit 40. As shown in FIG. 4, the rotating part 40 includes a pair of rotating main body parts 40 a and a connecting part 40 d. The rotating part 40 is made of a composite material in which glass fibers are combined with nylon resin, and has a self-lubricating property. The pair of rotating main body portions 40a are rod-shaped portions in which a through hole 40b is formed at one end and a through hole 40c is formed at the other end. In the pair of rotating main body portions 40a, the second attachment portions 42 extending in the axial direction of the through holes 40b and 40c are provided so as to project outward from between the through holes 40b and the through holes 40c. The connecting portion 40d is a portion that connects the insides of the pair of rotating main body portions 40a in the axial direction of the through holes 40b and 40c.

Referring back to FIG. 1 to FIG. The rotating unit 40 is a member that rotates around the second shaft 12 in response to depression of the pedal 30. The rotating portion 40 is configured to be rotatable with respect to the second shaft 12 by inserting the second shaft 12 (bolt 12b) into the through hole 40b (see FIG. 4). The 4th axis | shaft 14 comprised from a metal shaft is press-fit in the through-hole 40c (refer FIG. 4) of the rotation part 40. FIG.

The second attachment portion 42 is inserted into the guide hole 23c, and the end portion of the second attachment portion 42 protrudes outside the space between the pair of side plates 23. In this state, the spring 60 is attached to the end of the second attachment portion 42. The second mounting portion 42 moves in the guide hole 23c as the rotating portion 40 rotates.

The rotating unit 40 is slightly separated from the pedal 30 at the initial position of the pedal 30. The rotating part 40 is provided with a cushion 41 at a position where there is a possibility of contact with the pedal 30. When the pedal 30 rotates upward from the initial position, the cushion 41 can suppress a striking sound and an impact caused by contact between the pedal 30 and the rotating unit 40.

The connecting portion 50 is a member that connects the pedal 30 and the rotating portion 40 via the third shaft 13 and the fourth shaft 14. The connecting portion 50 is a rod-like member having a width substantially equal to the width between the pair of rotating main body portions 40a. Through holes (not shown) into which the third shaft 13 and the fourth shaft 14 are inserted are formed at both ends of the rod-shaped member. The connection part 50 is comprised with the composite material which compounded the glass fiber in the nylon resin, and has self-lubricity. One end of the connecting portion 50 is penetrated by the third shaft 13 and is configured to be rotatable with respect to the third shaft 13. The connecting portion 50 is configured to be rotatable with respect to the fourth shaft 14 with the other end penetrating the fourth shaft 14.

The spring 60 is a tension coil spring that connects the first mounting portion 27 and the second mounting portion 42. The spring 60 imparts an urging force to the pedal 30 for returning the rotated pedal 30 to the initial position. The spring 60 is provided on both the left and right sides of the pedal device 10. The spring 60 is provided outside the space between the pair of side plates 23. Compared to the case where the spring 60 is provided between the pair of side plates 23, the dimension of the pair of side plates 23 in the facing direction can be suppressed. Furthermore, the space for the rotation part 40, the connection part 50, and the pedal 30 provided between a pair of side plate 23 facing can be ensured. As a result, the pedal device 10 can be reduced in size, and the rigidity and strength of the rotating unit 40, the connecting unit 50, and the pedal 30 can be improved by setting the dimensions of the rotating unit 40, the connecting unit 50, and the pedal 30 large.

The spring 60 connects the first mounting portion 27 and the second mounting portion 42 in a state where an urging force is applied. Therefore, when the pedal 30 is not depressed (the initial position of the pedal 30), the rotating unit 40 may be stopped at a predetermined position so that the distance from the first mounting unit 27 to the second mounting unit 42 is the shortest. it can. The shortest distance is that the second attachment portion 42 is located on a line segment connecting the second shaft 12 and the first attachment portion 27 in a side view (in the axial view of the second shaft 12). Is the case. In addition, by stopping the rotating part 40, the connecting part 50 rotatably supported by the rotating part 40 is stopped at a predetermined position, and the pedal 30 rotatably supported by the connecting part 50 is stopped at the initial position. be able to.

Actually, at the initial position of the pedal 30, the distance from the first mounting portion 27 in the side view is the shortest due to the relationship between the weight of the pedal 30, the rotating portion 40, the connecting portion 50, etc. and the urging force of the spring 60. The second mounting portion 42 is positioned slightly below the position (the line connecting the second shaft 12 and the first mounting portion 27). However, in order to simplify the description in this specification, it is assumed that the distance from the first mounting portion 27 to the second mounting portion 42 is the shortest at the initial position of the pedal 30.

The sensor unit 70 is a member that detects the operation state of the pedal 30. The sensor unit 70 includes a main body 71, a pedal sensor 72, a first buffer material 73 (elastic body), a double-sided adhesive tape 74, a sheet metal 75, and a second buffer material 76 (elastic body).

The main body 71 is a member attached to the surface of the bottom plate 22 on the pedal 30 side. The main body 71 is provided with an output terminal 77 for outputting the detection result of the pedal sensor 72 to an external device (not shown). The pedal sensor 72 is a disc-shaped vibration sensor made of a piezo sensor, and mainly detects deformation in the thickness direction. The pedal sensor 72 receives the pressing force from the pedal 30 and detects the operation state of the pedal 30.

The first buffer material 73 and the second buffer material 76 are members made of sponge. The first cushioning material 73 is a hat-like member that is bonded to the pedal 30 side surface of the pedal sensor 72. The second cushioning material 76 is a cylindrical member whose both end surfaces are bonded to the sheet metal 75 and the main body 71. A disc-shaped double-sided adhesive tape 74 having cushioning properties is bonded to the surface of the pedal sensor 72 on the bottom plate 22 side. The pedal sensor 72 is bonded to the sheet metal 75 via the double-sided adhesive tape 74. Since the second cushioning material 76 is provided between the pedal sensor 72 and the bottom plate 22, it is possible to suppress vibrations and shocks transmitted from the bottom plate 22 to the pedal sensor 72. Thereby, the erroneous detection of the pedal sensor 72 can be suppressed. The first cushioning material 73 and the second cushioning material 76 can be made of rubber, thermoplastic elastomer, felt, or the like.

The sheet metal 75 is a member for ensuring the detection sensitivity of the pedal sensor 72. A pedal sensor 72 is sandwiched between a first cushioning material 73 and a second cushioning material 76 that are relatively deformable. Therefore, the pedal sensor 72 may not be easily deformed, and the deformation of the pedal sensor 72 may be complicated. However, a sheet metal 75 is provided between the pedal sensor 72 and the second cushioning material 76, and the pedal sensor 72 is bonded to the sheet metal 75 via the double-sided adhesive tape 74. As a result, the pedal sensor 72 can be deformed by the double-sided adhesive tape 74, and the deformation of the pedal sensor 72 can be stabilized based on the sheet metal 75. Thereby, the detection sensitivity of the pedal sensor 72 is securable.

It is also possible to provide a sheet metal 75 between the pedal sensor 72 and the first cushioning material 73 and adhere the pedal sensor 72 to the sheet metal 75 via the double-sided adhesive tape 74. In this case as well, the deformation of the pedal sensor 72 can be stabilized based on the sheet metal 75 while the pedal sensor 72 can be deformed by the double-sided adhesive tape 74. As a result, the detection sensitivity of the pedal sensor 72 can be ensured.

Next, the operation of the pedal device 10 will be described with reference to FIGS. 2, 5, 6 and 7. FIG. 5 is a cross-sectional view of the pedal device 10 showing the moment when the sensor unit 70 and the pedal 30 come into contact with each other. FIG. 6 is a cross-sectional view of the pedal device 10 showing the lowest position of the pedal 30. FIG. 7 is a graph schematically showing pedal angle-pedal reaction force. In FIG. 7, a graph A of pedal angle-pedal reaction force of the pedal device 10 is shown by a solid line. In FIG. 7, a graph B of pedal angle-pedal reaction force of a conventional pedal device (for example, the pedal device of Patent Document 1) that strikes the hit portion according to the rotation of the pedal is indicated by a broken line. The pedal angle is an angle of the pedal 30 with respect to the bottom plate 22 (floor surface) and becomes smaller as the pedal 30 is depressed. The pedal reaction force is a reaction force (such as an urging force of the spring 60) that acts on the performer from the pedal 30 when the pedal 30 is depressed.

2. When the performer depresses (operates) the pedal 30 at the initial position shown in FIG. 2, the pedal 30 rotates in one direction (counterclockwise in FIG. 2) about the first shaft 11. And according to rotation of the pedal 30, the 3rd axis | shaft 13 is pushed down below. Thereby, the connection part 50 supported by the 3rd axis | shaft 13 is pushed down. And the rotation part 40 supported by the connection part 50 by the 4th axis | shaft 14 rotates to one direction (FIG. 2 clockwise) centering on the 2nd axis | shaft 12. As shown in FIG. When the depression of the pedal 30 is released, the rotating portion 40 and the connecting portion 50 are moved in the reverse direction by the urging force of the spring 60 to return the pedal 30 to the initial position. Thus, the pedal device 10 constitutes a crank mechanism that rotates the rotating unit 40 in accordance with the operation of the pedal 30.

As shown in FIG. 5, when the pedal 30 and the sensor unit 70 (first cushioning material 73) come into contact with each other when the player depresses the pedal 30, the pedal 30 pushes against the pedal sensor 72 via the first cushioning material 73. Pressure acts. Thus, the pedal sensor 72 can detect that the performer has depressed the pedal 30 by a predetermined amount. Since the pedal sensor 72 is a piezo sensor, it is possible to detect the intensity of impact and vibration when the pedal 30 and the sensor unit 70 come into contact with each other. Accordingly, since it is possible to determine the level of depression of the pedal 30 by the player, an electronic musical tone having a tone color and volume corresponding to the level of depression can be generated from an external device (not shown).

Since the pedal 30 is in contact with the first buffer material 73 of the sensor unit 70, the first buffer material 73 can suppress a striking sound and an impact caused by contact between the pedal 30 and the sensor unit 70. The elastic modulus of the first cushioning material 73 is set such that a pressing force acts from the pedal 30 to the pedal sensor 72 when the pedal 30 and the sensor unit 70 are in contact with each other.

The player further depresses the pedal 30 from the state where the pedal 30 and the sensor unit 70 are in contact (the pressing force from the pedal 30 is applied to the pedal sensor 72). In this case, the first cushioning material 73 and the second cushioning material 76 are elastically deformed and the rotation of the pedal 30 is allowed. Then, as shown in FIG. 6, the pedal 30 rotates to a position where the second shaft 12, the third shaft 13, and the fourth shaft 14 are included in the same plane. Since the position where the second shaft 12, the third shaft 13, and the fourth shaft 14 are included in the same plane is the dead point of the crank mechanism, it is structurally impossible to depress the pedal 30 any more. Therefore, the position where the second shaft 12, the third shaft 13, and the fourth shaft 14 are included in the same plane is the lowest position of the pedal 30.

The distance from the first mounting portion 27 (the length of the spring 60) of the second mounting portion 42 is set to the shortest at the initial position of the pedal 30. The second mounting portion 42 rotates about 90 ° around the second shaft 12 when the pedal 30 rotates from the initial position to the lowest position. By setting in this way, as the pedal 30 approaches the lowest position from the initial position (as the second mounting portion 42 rotates), the second mounting portion 42 is separated from the first mounting portion 27 (the spring 60). Increase the length).

The length of the portion where the spring 60 functions (extends or contracts) as a spring (pedal) with respect to the distance between the first mounting portion 27 and the second mounting portion 42 (45 mm in the present embodiment at the initial position of the pedal 30). In the present embodiment, 27 mm is small at the initial position of 30. However, the increasing rate of the distance between the first mounting portion 27 and the second mounting portion 42 according to the rotation of the pedal 30 is equal to the increasing rate of the length of the portion where the spring 60 expands and contracts according to the rotation of the pedal 30.

If the angle at which the second mounting portion 42 rotates by rotation of the pedal 30 from the initial position to the lowest position is 180 ° or less, the first mounting portion 27 increases from the first mounting portion 27 as the pedal 30 approaches the lowest position from the initial position. 2 The attachment part 42 can be released. Thereby, the urging | biasing force by the spring 60 can be enlarged, so that the pedal 30 approaches the lowest position from an initial position. Therefore, the kinetic energy of the pedal 30 can be reduced by the spring 60 as the pedal 30 approaches the lowest position. As a result, since the impact and sound when the rotation of the pedal 30 stops can be reduced, the silent performance when the pedal 30 is operated can be improved.

Further, as the pedal 30 approaches the lowest position from the initial position, the urging force by the spring 60 can be increased, so that a resistance (pedal reaction force) that increases with the amount of depression of the pedal 30 from the initial position is played from the pedal 30. Can be granted. As a result, the operational feeling of the pedal 30 can be ensured.

Since the second mounting portion 42 rotates around the second shaft 12, the distance between the first mounting portion 27 and the second mounting portion 42 (the length of the spring 60) as the pedal 30 approaches the lowest position from the initial position. ) Increase rate. As a result, as shown in FIG. 7, the pedal reaction force (the urging force of the spring 60) can be increased in an accelerated and continuous manner according to the depression of the pedal 30. That is, the shape of the graph A of the pedal device 10 is a relatively smooth curve from the initial position (left end of the sheet) to the lowest position (right end of the sheet).

On the other hand, in the graph B of the conventional pedal device that hits the hit part according to the rotation of the pedal, the way of increasing the pedal reaction force changes rapidly before and after the point C hitting the hit part. In the graph B, when the pedal angle is larger than the point C (before hitting the hit portion), the pedal reaction force slightly increases due to the biasing force of the spring for returning the pedal to the initial position. When the pedal is stepped on and the pedal angle becomes smaller than point C (the hit portion is hit), the pedal stops rotating due to the hit (contact) on the hit portion. Therefore, a striking sound is generated, and the pedal reaction force suddenly increases due to contact with the hit portion.

The pedal device 10 does not stop the rotation of the pedal 30 by hitting the hit portion, unlike the conventional pedal device. That is, the pedal device 10 has a rotation range of the pedal 30 from the initial position to the lowest position. Therefore, the pedal 30 can be rotated to the limit of the player's stepping on. Thereby, since it can prevent that the pedal 30 hits a hit | damage part like the conventional pedal apparatus and a striking sound and an impact generate | occur | produce, the silent performance at the time of operation of the pedal 30 can be improved.

Further, the pedal device 10 can increase the pedal reaction force in the vicinity of the lowest position by using the spring 60 having a larger spring constant than the spring of the conventional pedal device. Thereby, the rotational speed of the pedal 30 can be sufficiently lowered before the pedal 30 reaches the lowest position. As a result, since the impact and sound when the pedal 30 rotates to the lowest position and the rotation of the pedal 30 stops can be reduced, the silent performance when operating the pedal 30 can be improved. The number of springs 60 and the spring constant of the springs 60 are appropriately adjusted in consideration of the balance between the force required to depress the pedal 30 and the pedal reaction force near the lowest position.

Furthermore, the greater the angle at which the second mounting portion 42 rotates due to the rotation of the pedal 30 from the initial position to the lowest position, the greater the elongation of the spring 60. As a result, the biasing force of the spring 60 near the lowermost position is increased, and the pedal reaction force near the lowermost position can be increased. Since the impact and sound when the rotation of the pedal 30 stops at the lowest position can be reduced, the silent performance when operating the pedal 30 can be improved.

The greater the distance from the second shaft 12 to the second mounting portion 42 (20 mm in this embodiment) relative to the distance from the second shaft 12 to the first mounting portion 27 (65 mm in this embodiment), The elongation rate of the spring 60 according to the amount of depression of the pedal 30 can be increased. That is, the smaller the value obtained by dividing the distance from the second shaft 12 to the first mounting portion 27 by the distance from the second shaft 12 to the second mounting portion 42, the smaller the pedal reaction force according to the depression amount of the pedal 30. Increase rate can be increased. As a result, the pedal reaction force near the lowest position can be increased.

A value obtained by dividing the distance from the second shaft 12 to the first mounting portion 27 by the distance from the second shaft 12 to the second mounting portion 42 (about 3.25 in the present embodiment) is set to 4 or less. Thus, the pedal reaction force in the vicinity of the lowest position can be increased. Thereby, the rotational speed of the pedal 30 can be sufficiently lowered before the pedal 30 reaches the lowest position. As a result, the impact and sound when the rotation of the pedal 30 stops at the lowest position can be reduced, and the silent performance when the pedal 30 is operated can be improved.

More preferably, a value obtained by dividing the distance from the second shaft 12 to the first mounting portion 27 by the distance from the second shaft 12 to the second mounting portion 42 is set to 3.5 or less. More preferably, a value obtained by dividing the distance from the second shaft 12 to the first mounting portion 27 by the distance from the second shaft 12 to the second mounting portion 42 is set to 3.3 or less. In these cases, the pedal reaction force in the vicinity of the lowest position can be further increased, so that the silent performance when the pedal 30 is operated can be further improved.

In the pedal device 10, the first cushioning material 73 and the second cushioning material 76 are elastically deformed to allow the pedal 30 to rotate. Therefore, the pedal sensor 72 can detect that the pedal 30 is depressed by a predetermined amount without hindering the rotation of the pedal 30 by the first cushioning material 73 and the second cushioning material 76. As a result, the pedal sensor 72 can detect the depression of the pedal 30 while improving the silent performance when the pedal 30 is operated.

When the player depresses the pedal 30 vigorously, the rotating unit 40 may exceed the position corresponding to the lowest position of the pedal 30. Further, when releasing the depression of the pedal 30, the rotating portion 40 may exceed the position corresponding to the initial position of the pedal 30 due to the biasing force of the spring 60. Therefore, a predetermined gap is provided between the second mounting portion 42 and the both ends of the guide hole 23c at the initial position and the lowest position of the pedal 30, respectively. Thereby, even if the rotation part 40 exceeds the position corresponding to the initial position and the lowest position of the pedal 30, if the exceeding length is less than the predetermined gap, the second mounting part 42 is connected to both ends of the guide hole 23c. You can avoid touching. Thereby, the silent performance at the time of operation of the pedal 30 is securable.

Further, when the rotating unit 40 exceeds the position corresponding to the lowest position of the pedal 30, the pedal 30 rotates from the lowest position toward the initial position. Since the weight 35 is attached to the pedal 30, the downward inertia force acting on the pedal 30 rotated to the lowest position can be increased. This inertial force makes it difficult to rotate the pedal 30 from the lowest position toward the initial position. As a result, the rotating unit 40 can hardly exceed the position corresponding to the lowest position of the pedal 30.

Since the rotating part 40 slides with respect to the second shaft 12, the rotating part 40 can be reduced in size compared to the case where a bearing is provided between the rotating part 40 and the second shaft 12. Similarly, since the connecting portion 50 slides with respect to the third shaft 13 and the fourth shaft 14, the connecting portion 50 is connected as compared with the case where a bearing is provided between the connecting portion 50 and the third shaft 13 and the fourth shaft 14. The part 50 can be reduced in size.

Furthermore, the rotating part 40 and the connecting part 50 have self-lubricating properties. Therefore, the rotating unit 40 can be rotated (slid) relatively smoothly around the second shaft 12 without providing a bearing between the rotating unit 40 and the second shaft 12. Further, even if no bearing is provided between the connecting portion 50 and the third shaft 13 and the fourth shaft 14, the connecting portion 50 rotates (slids) relatively smoothly around the third shaft 13 and the fourth shaft 14. ). As a result, the rotating part 40 and the connecting part 50 can be downsized while the rotating part 40 and the connecting part 50 are smoothly rotated. In the pedal device 10, resistance is given to the performer from the pedal 30 by the spring 60 in response to the depression of the pedal 30 from the initial position. Therefore, the player can hardly feel the resistance caused by the sliding of the rotating part 40 and the connecting part 50 with each of the shafts 12, 13 and 14.

Next, a second embodiment will be described with reference to FIGS. In 1st Embodiment, the pedal apparatus 10 used for the electronic musical instrument which simulated percussion instruments, such as a bass drum, was demonstrated. On the other hand, in 2nd Embodiment, the pedal apparatus 100 used for the electronic musical instrument (electronic hi-hat 80) which simulated the hi-hat cymbal is demonstrated. In addition, about the part same as 1st Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted.

First, the electronic hi-hat 80 will be described with reference to FIGS. FIG. 8 is a side view of the pedal device 100 attached to the hi-hat stand 81 in the second embodiment. FIG. 8 is an enlarged perspective view of a part of the hi-hat stand 81. As shown in FIG. 8, the electronic hi-hat 80 is an electronic musical instrument that emits electronic musical tones by hitting a cymbal pad 82 mounted on a hi-hat stand 81. The electronic musical sound is produced by detecting a hit by a sensor (not shown) provided on the cymbal pad 82 and outputting the detection result to an external device (not shown).

As shown in FIGS. 8 and 9, the hi-hat stand 81 includes a hollow shaft 83, a rod 84, a tripod 85, and a stand connector 86. The rod 84 is a part where the cymbal pad 82 is fixed by being inserted into the hollow shaft 83. The tripod 85 is a part that supports the hollow shaft 83 in a self-supporting manner. In the hi-hat stand 81, the lower end of the rod 84 and the rod mounting portion 87 connected to the bolt hole 34 of the pedal 120 of the pedal device 100 are connected by a chain 88. As a result, the rod 84 and the cymbal pad 82 fixed to the rod 84 move up and down in accordance with the operation of the pedal 120.

When the pedal 120 is depressed, the rod 84 and the cymbal pad 82 are lowered, and the cymbal pad 82 comes into contact with the upper portion 83a of the hollow shaft 83. This state is called a closed state. On the other hand, when the pedal 120 is released, the rod 84 and the cymbal pad 82 are raised. This state is called an open state. In the acoustic hi-hat cymbal, the tone of the musical sound due to the impact differs between the open state and the closed state.

The stand connector 86 is a part where the pedal device 100 is mounted. The stand connector 86 is attached to the lower part of the hollow shaft 83. The stand connector 86 is formed to be bifurcated so as to correspond to the pair of side plates 23. The stand connector 86 is provided with a protruding portion 89 that is inserted into the rear grounding portion 111 of the pedal device 100.

Next, the pedal device 100 will be described with reference to FIGS. 10 and 11. FIG. 10 is a side view of the pedal device 100. FIG. 11 is a cross-sectional view of the pedal device 100. As shown in FIGS. 10 and 11, the pedal device 100 includes a base portion 110, a pedal 120, a rotating portion 40, a connecting portion 50, a spring 60, and a sensor portion 130.

The base 110 is a member that becomes a base of the pedal device 100 and is placed on the floor surface. The base part 110 is formed by attaching a front grounding part 25 and a rear grounding part 111 to a plate-like frame 21. In the present embodiment, the first attachment portion 27 is attached to the second attachment hole 23 e of the side plate 23 of the frame 21.

The rear grounding portion 111 is a rubber member that receives the load on the rear side of the pedal device 100, and covers the leg portion 22e. The rear grounding portion 111 is inserted from the outside in the left-right direction of the leg portion 22e, and the rear grounding portion 111 is inserted into the leg portion 22e. In this state, the rear grounding part 111 is fixed to the leg part 22e by attaching the bolts 28 penetrating the leg part 22e and the rear grounding part 111 in the vertical direction. Further, the rear grounding portion 111 is formed with an insertion hole 112 into which the protruding portion 89 can be inserted at the rear portion. With the protrusion 89 inserted into the insertion hole 112, the stand connector 86 is fixed to the rear grounding part 111 by attaching a bolt 114 passing through the insertion hole 112 and the protrusion 89 in the vertical direction. As a result, the pedal device 100 is attached to the hi-hat stand 81.

The pedal 120 is a member that rotates around the first axis 11 when the performer's foot is placed on the front side and the performer depresses the pedal 120. The pedal 120 is rotatably supported by the base 110 on the first shaft 11. The pedal 120 is formed to extend from the first end 31 toward the second end 32 in a long plate shape. In the pedal 120, a plate member 121 (elastic body) is fixed to the back side with bolts 122.

The plate member 121 is a rectangular metal member. The plate member 121 is attached to the back side of the pedal 120 in a cantilever state in which an end fixed to the bolt 122 is a fixed end and an end opposite to the fixed end is a free end. The plate member 121 is in contact with the sensor portion 130 (the buffer material 133) and the free end side during the rotation of the pedal 120 from the initial position to the lowest position. The elastic modulus of the plate member 121 is set so that a pressing force is applied from the pedal 120 to the sensor unit 130 via the plate member 121 when the plate member 121 and the sensor unit 130 are in contact with each other.

The sensor unit 130 is a member that detects the operation state of the pedal 120. The sensor unit 130 includes a main body 131, a pedal sensor 132, and a cushioning material 133 (elastic body). The buffer material 133 is a plate-like member made of sponge. The cushioning material 133 is bonded to the surface of the pedal sensor 132 on the pedal 120 side.

The main body 131 is a member attached to the surface of the bottom plate 22 on the pedal 120 side. The main body 131 is provided with an output terminal 134 for outputting the detection result of the pedal sensor 132 to an external device (not shown). The pedal sensor 132 is a sheet-like pressure sensor made of a membrane switch. The pedal sensor 132 is bonded to the main body 131 and receives the pressing force from the pedal 120 to detect the operation state of the pedal 120. The resistance value of the pedal sensor 132 decreases as the area of the pressed portion increases. Note that the pedal sensor 132 is not limited to one whose resistance value decreases as the area of the pressed portion increases, but a pedal sensor 132 whose resistance value decreases as the pressing force increases can be used.

In the pedal device 100, the plate member 121 of the pedal 120 and the cushioning material 133 of the sensor unit 130 come into contact with each other when the player depresses the pedal 120. When the performer further steps on the pedal 120 from the state where the plate member 121 and the cushioning material 133 are in contact with each other, the plate member 121 and the cushioning material 133 are elastically deformed to allow the pedal 120 to rotate. Then, the pedal 120 rotates to the lowest position.

When the pedal 120 is stepped on, the free end side of the plate member 121 in a cantilever state contacts the cushioning material 133. Therefore, as the pedal 120 approaches the lowermost position, the contact area between the plate member 121 and the cushioning material 133 increases, and the pressing force per unit area from the plate member 121 to the cushioning material 133 increases. Therefore, as the pedal 120 approaches the lowermost position, the area where the pressing force acts from the plate member 121 to the pedal sensor 132 via the cushioning material 133 increases. Then, the force (the force obtained by multiplying the pressing force per unit area by the area) that the plate member 121 presses the pedal sensor 132 through the cushioning material 133 increases. As a result, the resistance value of the pedal sensor 132 decreases as the pedal 120 approaches the lowest position, so that the operation state (depression amount) of the pedal 120 can be determined by the pedal sensor 132.

The pedal device 100 can determine a state where no pressing force is applied to the pedal sensor 132 as an open state. Further, when the pressing force is applied to the pedal sensor 132 and the depression amount of the pedal 120 is less than a predetermined value (the resistance value of the pedal sensor 132 is larger than the predetermined value), it can be determined as a half-open state. Furthermore, when the pressing force is applied to the pedal sensor 132 and the depression amount of the pedal 120 is equal to or larger than a predetermined value (the resistance value of the pedal sensor 132 is equal to or smaller than the predetermined value), it can be determined as the closed state. Thereby, when the electronic hi-hat 80 equipped with the pedal device 100 is played, electronic musical tones corresponding to the open state, the half-open state, and the closed state can be generated.

In this embodiment, when the pedal 120 is rotated to the lowest position, the cymbal pad 82 is set in contact with the upper portion 83a of the hollow shaft 83 (becomes a closed state). Accordingly, when the cymbal pad 82 is hit with the pedal 120 depressed to the limit, the cymbal pad 82 is in contact with the upper portion 83a of the hollow shaft 83, so that the cymbal pad 82 can hardly be shaken. As a result, the movement of the closed acoustic hi-hat cymbal can be simulated.

According to the pedal device 100 as described above, since the sensor unit 130 is pressed on the free end side of the plate member 121 in a cantilever state, the plate member 121 can be easily elastically deformed. Further, the pressing force to the sensor unit 130 can be secured by the restoring force of the elastically deformed plate member 121. As a result, the silent performance when operating the pedal 120 can be improved, and the detection sensitivity of the pedal sensor 132 can be improved.

The first attachment portion 27 is attached to the second attachment hole 23e. Thereby, the initial position of the pedal 120 can be brought closer to the bottom plate 22 than the initial position of the pedal 30 in the first embodiment (when the first mounting portion 27 is mounted in the first mounting hole 23d). Note that the lowest position of the pedal 120 is the same as the lowest position of the pedal 30 of the first embodiment. Therefore, when the pedal 120 rotates from the initial position to the lowest position, the rotation angle of the second attachment portion 42 that rotates about the second shaft 12 can be made smaller than 90 °. As a result, the resistance applied to the performer from the pedal 120 at the lowest position of the pedal 120 can be reduced. Therefore, the stepping force for depressing the pedal 120 to the lowest position or maintaining the pedal 120 at the lowermost position can be reduced.

Next, a third embodiment will be described with reference to FIG. In 2nd Embodiment, the case where the pedal sensor 132 was pressed by the free end side of the board member 121 fixed to the back side of the pedal 120 in the cantilever state was demonstrated. In contrast, in the third embodiment, a case will be described in which the pedal 30 directly contacts the cushioning material 142 and the pedal sensor 132 is pressed by the pedal 30 via the cushioning material 142. In addition, about the part same as 1st, 2 embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted.

FIG. 12 is a cross-sectional view of the pedal device 140 according to the third embodiment. As shown in FIG. 12, in the sensor unit 141 of the pedal device 140, a cushioning material 142 (elastic body) is bonded to the surface of the pedal sensor 132 on the pedal 30 side. The buffer material 142 is a member made of sponge. The surface of the cushioning material 142 on the pedal 30 side is inclined downward toward the first shaft 11 side with respect to the pedal sensor 132. The elastic modulus of the cushioning material 142 is set such that a pressing force acts on the pedal sensor 132 from the pedal 30 via the cushioning material 142 when the pedal 30 and the cushioning material 142 are in contact with each other.

In the pedal device 140, the pedal 30 and the cushioning material 142 come into contact with each other when the player depresses the pedal 30. When the performer further depresses the pedal 30 from the state where the pedal 30 and the cushioning material 142 are in contact with each other, the cushioning material 142 is elastically deformed to allow the pedal 30 to rotate, and the pedal 30 rotates to the lowest position.

The angle of inclination of the surface on the pedal 30 side is set so that the contact portion with the pedal 30 becomes larger as the pedal 30 approaches the lowermost position. As a result, the closer the pedal 30 is to the lowest position, the larger the area on which the pressing force acts from the pedal 30 to the pedal sensor 132 via the cushioning material 142. The force with which the pedal 30 presses the pedal sensor 132 via the cushioning material 142 is increased. As a result, the resistance value of the pedal sensor 132 decreases as the pedal 30 approaches the lowest position, so that the pedal sensor 132 can determine the operation state (depression amount) of the pedal 30.

Next, a fourth embodiment will be described with reference to FIGS. In the first embodiment, the crank mechanism in which the third shaft 13 is located below the second shaft 12 has been described. In contrast, in the fourth embodiment, a crank mechanism in which the third shaft 13 is positioned above the second shaft 151 will be described. In addition, about the part same as 1st Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted.

First, the pedal device 150 when the pedal 30 is in the initial position will be described with reference to FIGS. 13 and 14. FIG. 13 is a schematic diagram of the pedal device 150 showing an initial position in the third embodiment. FIG. 14 is a schematic diagram of the pedal device 150 viewed from the direction of arrow XIV in FIG. In FIG. 14, the pedal 30 is omitted.

As shown in FIGS. 13 and 14, the pedal device 150 includes a pedal 30, a rotating part 152, a connecting part 153, and a spring 60. The rotating part 152 is rotatably supported by a second shaft 151 on a side plate 23 (not shown in the present embodiment) rising from the bottom plate 22. The connecting portion 153 is rotatably supported by the pedal 30 on the third shaft 13. The connecting portion 153 is rotatably supported by the rotating portion 152 on the fourth shaft 14. The first attachment portion 27 to which the spring 60 is attached is provided on the bottom plate 22. The third shaft 13, the fourth shaft 14, the second shaft 151, and the first shaft 11 are positioned in this order from above.

The second shaft 151 is a pair of members divided into two in the axial direction. The second shaft 151 is rotatably supported by the side plate 23 rising from the bottom plate 22. The rotating part 152 is a pair of members to which both ends of the fourth shaft 14 are fixed. The end portions of the second shaft 151 formed by being divided are fixed to the pair of rotating portions 152, respectively. The second shaft 151, the rotating unit 152, and the fourth shaft 14 rotate integrally around the second shaft 151 in response to depression of the pedal 30.

The rotating portion 152 is provided with a second mounting portion 42 to which the spring 60 is mounted at a predetermined distance from the second shaft 151. The second attachment portion 42 is disposed such that the second shaft 151 is positioned between the second shaft 42 and the fourth shaft 14. In the pedal device 150, the distance from the second shaft 151 to the first mounting portion 27 is set to 67 mm at the initial position of the pedal 30. Further, at the initial position, the distance from the second shaft 151 to the second mounting portion 42 is set to 17 mm.

The connecting portion 153 is a member that connects the pedal 30 and the rotating portion 152 via the third shaft 13 and the fourth shaft 14. The connecting portion 153 is supported by the fourth shaft 14 between the pair of rotating portions 152. The connecting portion 153 is formed such that the distance between the third shaft 13 and the fourth shaft 14 is larger than the distance between the second shaft 151 and the fourth shaft 14.

Next, the pedal device 150 when the pedal 30 is at the lowest position will be described with reference to FIG. FIG. 15 is a schematic diagram of the pedal device 150 showing the lowermost position. In the pedal device 150, when the player steps on the pedal 30 at the initial position shown in FIG. 13, the connecting portion 153 is pushed down. Then, the rotating unit 152 rotates in one direction (counterclockwise in FIG. 13) about the second shaft 151. Thereby, as the pedal 30 is depressed from the initial position, the rotating portion 152 and the connecting portion 153 are folded around the fourth shaft 14. Then, as shown in FIG. 15, the pedal 30 is depressed to a position where the second shaft 151, the third shaft 13 and the fourth shaft 14 are included in the same plane.

Since the position where the second shaft 151, the third shaft 13 and the fourth shaft 14 are included in the same plane is the dead point of the crank mechanism, it is structurally impossible to depress the pedal 30 any more. Therefore, the position where the second shaft 151, the third shaft 13 and the fourth shaft 14 are included in the same plane is the lowest position of the pedal 30. Since the pedal device 150 can rotate the pedal 30 to the limit of the stepping on by the player, it is possible to improve the silent performance when the pedal 30 is operated as in the first embodiment.

As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to the said embodiment at all. It can be easily inferred that various improvements and modifications can be made without departing from the spirit of the present invention. For example, the shapes of the base portions 20 and 110, the pedal 30, the rotating portions 40 and 152, the connecting portions 50 and 153, and the like are examples, and various shapes are naturally adopted.

In each of the above embodiments, the case where the spring 60 is a tension coil spring has been described, but the present invention is not necessarily limited thereto. Naturally, it is possible to use a tension spring other than the tension coil spring for the spring 60. Further, not only the tension spring but also a compression spring can be used for the spring 60. In this case, the compression spring is set to be the longest at the initial position. It is also possible to use a torsion spring as the spring 60 to return the pedals 30 and 120 to their initial positions. The spring 60 is not limited to a metal, and a spring made of rubber or thermoplastic elastomer can also be used.

In the first, second, and third embodiments, the case where the position for attaching the first attachment portion 27 is selected from the first attachment hole 23d or the second attachment hole 23e has been described. However, the present invention is not necessarily limited thereto. It is also possible to provide an attachment hole in addition to the first attachment hole 23d and the second attachment hole 23e, and attach the first attachment portion 27 to the attachment hole. It is also possible to use holes, protrusions, and the like provided in the side plate 23 as the first mounting portion. By adjusting the position of the first mounting portion, the initial position of the pedal 30 can be changed as appropriate.

In the first embodiment, the case where the pedal sensor 72 is a vibration sensor made of a piezo sensor has been described. In the second and third embodiments, the case where the pedal sensor 132 is a pressure sensor including a membrane switch has been described. However, it is not necessarily limited to this. Of course, other vibration sensors and pressure sensors can be used. It is also possible to use a pressure sensor in the first embodiment. When the pedal sensor 72 is a vibration sensor, the operation state of the pedal 30 is detected when the pedal sensor 72 starts to receive a pressing force from the pedal 30. On the other hand, when the pedal sensor 72 is a pressure sensor, the operation state of the pedal 30 can be detected while the pedal sensor 72 receives a pressing force from the pedal 30. Therefore, when the pedal sensor 72 is a pressure sensor, it is possible to more accurately detect the strength of depression of the pedal 30 and the release of depression of the pedal 30.

In the first, second, and third embodiments, the case where the sensor units 70, 130, and 141 are attached to the surface of the bottom plate 22 on the pedals 30 and 120 side is described. However, the present invention is not limited to this. It is naturally possible to attach the sensor units 70, 130, and 141 to the pedals 30 and 120. It is also possible to attach the sensor units 70, 130, and 141 to the side plate 23. Also in this case, the second cushioning material 76 is disposed between the side plate 23 and the pedal sensor 72. Thereby, it can suppress that the vibration and impact from the side plate 23 are transmitted to the pedal sensor 72, and can suppress the erroneous detection of the pedal sensor 72.

In the first embodiment, the case where the rotating portion 40 and the connecting portion 50 are made of a composite material in which a glass fiber is combined with nylon resin (polyamide) has been described. However, it is not necessarily limited to this. As long as the material has strength and rigidity that can withstand the depression of the pedal 30, the material of the rotating portion 40 and the connecting portion 50 can be changed as appropriate.

Further, it is preferable that the material of the rotating portion 40 and the connecting portion 50 is a material having self-lubricating properties. A synthetic resin has a self-lubricating property if its crystallinity is high. Examples of synthetic resins having self-lubricating properties other than nylon (polyamide) include polyacetal, polytetrafluoroethylene, and polyolefin. Examples of materials having self-lubricating properties other than synthetic resins include graphite, molybdenum disulfide, and silver. In addition, it is possible to comprise the rotation part 40 and the connection part 50 other than the material which has self-lubricating property by using grease between the rotation part 40 and the connection part 50, and each axis | shaft 12,13,14. .

In the first embodiment, the first shaft 11 and the third shaft 13 are fixed to the pedal 30, the second shaft 12 is fixed to the side plate 23, and the fourth shaft 14 is fixed to the rotating unit 40. explained. However, it is not necessarily limited to this. It is naturally possible to fix the first shaft 11 to the front grounding portion 25 (base portion 20), the second shaft 12 to the rotating portion 40, and the third shaft 13 and the fourth shaft 14 to the connecting portion 50. is there. The shafts 11, 12, 13, 14 are not fixed, but flanges or pins are provided at both ends of the shafts 11, 12, 13, 14, and the shafts 11, 12, 13, 14 are operated during operation of the pedal device 10. 14 can be prevented.

In the first embodiment, the second mounting portion 42 is inserted into the guide hole 23 c provided in the side plate 23, and the end of the second mounting portion 42 is stretched outside the space between the pair of side plates 23. Explained when to put out. However, it is not necessarily limited to this. A cut can be provided instead of the guide hole 23c. The shape of the cut is appropriately set so that the second mounting portion 42 that moves according to the rotation of the pedal 30 does not contact the side plate 23.

In the first embodiment, the case where the sheet metal 75 is provided between the double-sided adhesive tape 74 and the second cushioning material 76 has been described, but the present invention is not necessarily limited thereto. It is naturally possible to provide a plate material having a predetermined rigidity (higher rigidity than the first buffer material 73 and the second buffer material 76) such as resin or ceramic between the double-sided adhesive tape 74 and the second buffer material 76. It is.

In the fourth embodiment, the case where the second shaft 151, the rotating unit 152, and the fourth shaft 14 rotate together has been described. However, the present invention is not limited to this. Of course, it is possible to fix the second shaft 151 to the side plate 23 and rotatably support the rotating portion 152 on the second shaft 151. In this case, it is preferable not to divide the second shaft 151 in the axial direction in order to ensure the strength of the second shaft 151. In addition, it is necessary to bend or curve the second shaft 151 and the connecting portion 153 so that the second shaft 151 and the connecting portion 153 do not contact at the lowest position of the pedal 30.

The crank mechanism of each of the above embodiments (the configuration in which the second shaft 12, 151, the third shaft 13, and the fourth shaft 14 are included in the same plane at the lowest position of the pedals 30, 120) is the same as that of each of the above embodiments. The present invention is not limited to the pedal device including the base portions 20 and 110 (frame 21) in the form, and can be applied to pedal devices having various shapes of base portions (frames). For example, the base (frame) which spanned the 2nd axis | shafts 12 and 151 to a pair of support | pillar, and connected a pair of support | pillar and the front grounding part 25 with the rod-shaped bottom face part is mentioned.

Further, the base parts 20 and 110 (frames 21) of the above-described embodiments can be applied not only to the pedal device of the crank mechanism but also to the pedal device of the chain or belt mechanism. Moreover, the base parts 20 and 110 (frame 21) of each said embodiment are not restricted to the pedal apparatus used for an electronic musical instrument, It is also possible to apply to the pedal apparatus used for an acoustic percussion instrument.

10, 100, 140, 150 Pedal device for musical instrument 11 First shaft 12, 151 Second shaft 20, 110 Base 22 Bottom plate 22a First end 22b Second end 22c Side edge 22e Leg portion 23 Side plate 23a Notch hole 24 Rib 30, 120 Pedal 40, 152 Rotating part 42 Second attachment part (attachment part)
60 spring

Claims (5)

1. A base placed on the floor,
   A pedal that is rotatably supported by the base at the first axis with a rotatable range from the initial position to the lowest position;
   A rotating part that is rotatably supported by the base part on a second axis parallel to the first axis and rotates according to the rotation of the pedal;
   A biasing member that applies a biasing force for returning the pedal rotated from the initial position to the initial position;
   The base is a bottom plate whose side edges extend from the first end toward the second end;
   A pair of side plates rising from the side edge on the second end side of the bottom plate,
   The bottom plate and the pair of side plates are formed from a single plate material,
   The second shaft is a musical instrument pedal device spanned between the pair of side plates.
2. The second shaft is fixed to the pair of side plates by connecting the pair of side plates to each other,
   The musical instrument pedal device according to claim 1, wherein the rotating portion slides relative to the second shaft.
3. 3. The musical instrument pedal device according to claim 1, wherein the base includes a rib that is formed integrally with the side plate and rises from the side edge of the bottom plate.
4. The pair of side plates has a notch hole formed upward from the side edge of the bottom plate,
   The musical instrument pedal device according to any one of claims 1 to 3, wherein the bottom plate is formed such that a leg portion having a dimension equal to or smaller than the size of the notch hole projects outward from the side edge at a position corresponding to the notch hole. .
5. The rotating part includes an attachment part with an end projecting outward from between the opposing side plates.
   The musical instrument pedal device according to any one of claims 1 to 4, wherein the urging member connects the base portion and the mounting portion outside the space between the pair of side plates facing each other.

Images