This invention relates to a pedal device used for playing of a drum such as a bass drum.
As disclosed in Japanese Patent Application Publication No. 2007-017805, a pedal device of this kind includes a base plate, a pedal, a chain, a rotary shaft, a beater, a tension coil spring, and others. Columns in a pair extend upward from the front end of the base plate. The rotary shaft is rotationally supported on the respective upper ends of the columns in a pair. The beater and a wheel are attached to the center of the rotary shaft. The pedal is rotationally attached to the rear end of the base plate. One end of the chain is coupled to the rotary shaft while being wound around the wheel. The opposite end of the chain is coupled to a free end of the pedal. The upper end of the tension coil spring is coupled through a coupling ring to a crank arm attached to an end portion of the rotary shaft. The lower end of the tension coil spring is coupled to the upper end of the bolt that adjusts the tension of the tension coil spring. The bolt is fixed to a bracket projecting from one of the columns with an upper nut and a lower nut in a pair. When the pedal is depressed against the biasing force of the tension coil spring, the beater is rotated by the chain, the wheel, and the rotary shaft to beat a bass drum. When the pedal is released from the depression, the biasing force of the tension coil spring makes the beater and the pedal return to their initial positions.
As shown in
It is an object of this invention to provide a pedal device for a drum that improves the operability of a pedal by making a spring swing by a smaller angle during operation on the pedal.
To solve the aforementioned problem, one aspect of this invention provides a pedal device for a drum. The pedal device includes: a unit body having a base and a column extending upward from a front end of the base; a pedal rotationally attached to a rear end of the base; a shaft supported on an upper end of the column; a beater provided on the shaft, the beater rotating around an axis of the shaft to beat a drum; a crank arm that rotates around the axis of the shaft together with the beater; a transmission member coupled to a free end of the pedal, the transmission member transmitting operating force of the pedal to the beater; and a spring with an upper end coupled to the crank arm and a lower end coupled to the unit body. The spring has an axis. The pedal is held in a standby position by the spring while the axis of the spring lies in a common plane with a reference line connecting the lower end of the spring and a rotation center of the crank arm. The operating force of the pedal is transmitted through the transmission member to the beater to rotate the beater and the crank arm rotating together with the beater makes the spring swing back and forth on the lower end of the spring as a fulcrum. The unit body is provided with a bracket that supports the spring in a manner allowing the spring to swing. The swinging fulcrum of the spring is provided on a lower surface of the bracket.
An embodiment that embodies a pedal device of this invention for a drum is described below by referring to
As shown in
The shaft 14 is rotationally supported on the respective upper ends of the columns 18 in a pair. The beater 15 and a wheel 22 are attached to the substantially central part of the shaft 14. One end of the chain belt 13 is fixed while being wound around the circumferential surface of the wheel 22. The opposite end of the chain belt 13 is fixed to a free end of the pedal 12 corresponding to the front end of the pedal 12. The chain belt 13 is supported by the wheel 22 and the pedal 12 to be pulled downward by the weight of the pedal 12 itself.
The upper end of the tension coil spring 16 is coupled to an end portion of the shaft 14 through a ring 24 and a crank arm 25. The lower end of the tension coil spring 16 is coupled through a bolt 26, an adjusting nut 28, and a locking nut 29 to a bracket 30 fixed to one of the columns 18. The tension coil spring 16 is supported by the ring 24 and the bolt 26 to be stretched along the axis of the column 18. In this condition, the tension coil spring 16 holds the beater 15 in a resting position of
The drum pedal 10 is used while a beating surface 15a of the beater 15 is arranged to face a bass drum not shown in the drawings and the base 17 is coupled to the bass drum. When a player depresses the pedal 12 of the drum pedal 10 with his or her foot, the force of the depression is transmitted through the chain belt 13 to the wheel 22. Then, the beater 15 rotates in a direction P of
As shown in
As shown in
The bracket body 31 has a front surface 31a, side surfaces 31b in a pair, a rear surface 31c, an upper surface 31d, and a lower surface 31e. The front surface 31a, the side surfaces 31b in a pair, and the rear surface 31c are arranged to surround the vertical hole 34. The front surface 31a is curved along an arc coaxial with the vertical hole 34. The front surface 31a and the side surfaces 31b in a pair together form a substantially U-shaped surface. The rear surface 31c is curved to have the same shape as the outer side surface of the column 18. The upper opening end 34a of the vertical hole 34 is formed in the upper surface 31d. The upper surface 31d is curved downward further in a position at a shorter distance from the center of the vertical hole 34 to each side surface 31b. The lower opening end 34b of the vertical hole 34 is formed in the lower surface 31e. The lower surface 31e is flat in a part except the lower opening end 34b.
The projection 33 contacts the adjusting nut 28. The projection 33 is a first contact part contacting the tension coil spring 16 indirectly through the bolt 26 and the adjusting nut 28. The projection 33 is formed of projections 33 in a pair with respect to an axis C34 of the vertical hole 34 as a center. The projection 33 is formed to have a substantially triangular sectional shape. The projection 33 has a tip 33a that has an arcuate sectional shape. The tip 33a of the projection 33 extends along a straight line perpendicular to the axis C34 of the vertical hole 34. The projection 33 is formed integrally with the lower surface of the bracket body 31 with the tip 33a pointed downward.
As shown in
A recess 37 that can fit the projection 33 of the bracket 30 is formed in the upper surface of the retainer 36. The recess 37 supports the tension coil spring 16 together with the bolt 26 and the adjusting and locking nuts 28 and 29 in a manner allowing the tension coil spring 16 to swing together with the bolt 26 and the adjusting and locking nuts 28 and 29. The recess 37 is a second contact part contacting the projection 33 of the bracket 30. The recess 37 is formed of two recesses 37 passing through an axis C39 of the screw hole 39. Each of the two recesses 37 extends along a straight line perpendicular to the axis C39 of the screw hole 39. The two recesses 37 cross each other at right angles on the axis C39 of the screw hole 39.
The two recesses 37 have the same shape and the same size. Each of the recesses 37 is formed to have a substantially triangular sectional shape. Each of the recesses 37 has a bottom surface 37a formed of an arcuate surface of an arcuate sectional shape and an opening surface 37b extending from the bottom surface 37a to be continuous with the upper surface of the retainer 36. The bottom surface 37a of the recess 37 in the retainer 36 has an R value set to be larger than that of the tip 33a of the projection 33 of the bracket 30. The recess 37 in the retainer 36 has a depth D set to be smaller than a height H of the projection 33 of the bracket 30. The recess 37 in the retainer 36 has a width set to be the same as that of the projection 33 of the bracket 30.
As shown in
The action of the aforementioned drum pedal 10 is described next by referring to
As shown by broken lines in
As shown by solid lines of
The pivot angle of the tension coil spring 16 in the drum pedal 10 of this embodiment and that of a tension coil spring 101 in a conventional drum pedal 110 are compared. A result of the comparison is described next by referring to
As shown in
As shown in
As shown in
As clearly seen from
Thus, this embodiment achieves the following effects.
(1) While being fixed to a position near the lower end of the column 18, the bracket 30 supports the tension coil spring 16 together with the bolt 26 and the adjusting and locking nuts 28 and 29 such that the tension coil spring 16 can swing together with the bolt 26 and the adjusting and locking nuts 28 and 29. The pivot fulcrum F16 of the tension coil spring 16 is provided on the lower surface of the bracket 30 contacting the adjusting nut 28. This structure reduces the pivot angle A16 that the axis C16 of the tension coil spring 16 forms with the reference line BL when the tension coil spring 16 pivots back and forth. Specifically, the pivot angle A16 of the tension coil spring 16 is reduced during operation on the pedal 12, thereby reducing the force PB of the horizontal component acting on the pivot fulcrum F16 of the tension coil spring 16. This suppresses the occurrence of backward and forward pivot motion of the entire drum pedal 10 together with the pivot motion of the tension coil spring 16, thereby improving the operability of the pedal 12. Reducing the pivot angle A16 of the tension coil spring 16 during operation on the pedal 12 reduces the force of friction occurring at the pivot fulcrum F16 of the tension coil spring 16. This allows smooth movement of the pedal 12 to further improve the operability of the pedal 12.
(2) The projection 33 of the bracket 30 is the first contact part contacting the tension coil spring 16 indirectly through the bolt 26 and the adjusting nut 28. The recess 37 in the adjusting nut 28 is the second contact part contacting the projection 33 of the bracket 30. This structure provides a fit between the projection 33, which is the first contact part, and the recess 37, which is the second contact part. Thus, the tension coil spring 16 is unlikely to come off the bracket 30 when pivoting back and forth during operation of the pedal 12.
(3) The tip 33a of the projection 33 has an arcuate sectional shape. The bottom surface 37a of the recess 37 is formed by an arcuate surface of an arcuate sectional shape. The bottom surface 37a of the recess 37 in the retainer 36 has an R value set to be larger than that of the tip 33a of the projection 33 of the bracket 30. This structure make point contact or line contact between the projection 33, which serves as the first contact part, and the recess 37, which serves as the second contact part. This further reduces the force of friction occurring at the pivot fulcrum F16 of the tension coil spring 16. This allows smoother movement of the pedal 12 to further improve the operability of the pedal 12.
(4) The depth D of the recess 37 in the retainer 36 is set to be less than the height H of the projection 33 of the bracket 30. As shown in
(5) The lower end of the bolt 26 is threaded to corresponding threads in the screw hole 39 in the adjusting nut 28. By operating the adjusting nut 28, the position of the bolt 26 in the direction of the axis is adjusted to control the tension of the tension coil spring 16. In this structure, by adjusting the position of the bolt 26 in the direction of the axis to move the position of the lower end of the tension coil spring 16 up and down, the tension of the tension coil spring 16 can be controlled. By controlling the tension of the tension coil spring 16, the feeling sensed during depression of the pedal 12 and the speed at which the beater 15 returns can be controlled.
(6) The tip 33a of the projection 33 extends along a straight line perpendicular to the axis C34 of the vertical hole 34. The two recesses 37 that can fit the projection 33 of the bracket 30 are formed in the upper surface of the retainer 36. Axes of the two recesses 37 cross each other at right angles at a point where they intersect the axis C39 of the screw hole 39. This structure, in which the recess 37 is formed in at least two or more positions of the retainer 36 of the adjusting nut 28, allows finer adjustment of the position of the bolt 26 in the direction of the axis than a structure in which the recess 37 formed in only one position. As a result, the tension of the tension coil spring 16 can be controlled more finely.
(7) The projection 33 is one of a pair of projections 33, and one projection 33 is located on each side of the axis C34 of the vertical hole 34, as indicated in
(8) The locking nut 29 is threaded to the upper end of the bolt 26. The adjusting nut 28 includes the tubular part 38 projecting from the upper surface of the retainer 36. The locking nut 29 is tightened on the bolt 26 until the locking nut 29 abuts on the tip of the tubular part 38 of the adjusting nut 28. In this way, the adjusting nut 28, which is threaded to the bolt 26, is locked with the locking nut 29. This can eliminate the development of backlash between the bolt 26 and the adjusting nut 28.
(9) The vertical hole 34 in the bracket 30 is formed in a tapered shape in a vertical section with the upper opening end 34a larger than the lower opening end 34b. This structure prevents interference between the circumferential wall of the vertical hole 34 in the bracket 30 and the tubular part 38 of the adjusting nut 28 from occurring when the tension coil spring 16 pivots back and forth.
(10) The projection 33 projects from the lower surface of the bracket body 31. The recess 37 is formed in the upper surface of the retainer 36. In this structure with the projection 33 provided on the lower surface of the bracket body 31 and the recess 37 in the upper surface of the adjusting nut 28, the pivot fulcrum F16 of the tension coil spring 16 can be set to be lower in position than the bracket 30. This can reduce the pivot angle A16 further the axis C16 of the tension coil spring 16 forms with the reference line BL when the tension coil spring 16 pivots back and forth. Specifically, the pivot angle A16 of the tension coil spring 16 is reduced further during operation on the pedal 12, thereby further improving the operability of the pedal 12.
This embodiment can be changed as follows.
As shown in
As shown by solid lines in
This embodiment employs the structure where the tension coil spring 16 pivots together with the bolt 26 and the adjusting and locking nuts 28 and 29 relative to the bracket 30. However, this is not limitation requirement. As an example, the bracket 30 may support the lower end of the tension coil spring 16 directly while the bolt 26 and the adjusting and locking nuts 28 and 29 are omitted. In this structure, to prevent the tension coil spring 16 from coming off the bracket 30, a projection, as the second contact part, may be provided on the tension coil spring 16 and a recess, as the first contact part, may be formed in the lower surface of the bracket 30.
In this embodiment, the tip 33a of an arcuate sectional shape of the projection 33 may be replaced by a pointed tip. The bottom surface 37a formed of an arcuate surface of the recess 37 may be replaced by a bottom surface of a triangular sectional shape.
In this embodiment, the tip 33a of the projection 33 extends along a straight line perpendicular to the axis C34 of the vertical hole 34 to form a line contact with the bottom surface 37a of the recess 37. However, this is not limitation requirement. As an example, the tip 33a of the projection 33 may be formed in a conical or spherical shape to make point contact with the bottom surface 37a of the recess 37.
In this embodiment, the number of the recesses 37 formed in the upper surface of the retainer 36 may be changed to one or three or more.
In this embodiment, the locking nut 29 threaded to the upper end of the bolt 26 may be omitted or the tubular part 38 may be omitted from the adjusting nut 28.
In this embodiment, the vertical section of the vertical hole 34 in the bracket 30 may be changed from a tapered shape to a straight shape as long as such a shape can prevent interference between the circumferential wall of the vertical hole 34 and the tubular part 38 of the adjusting nut 28.
In this embodiment, the unit body 11 may have only one column instead of the columns 18 in a pair extending upward from the front end of the base 17. In this structure, the shaft 14 becomes a cantilever supported on the upper end of one column.
In this embodiment, the shaft 14 may not be required to be rotationally supported on the respective upper ends of the columns 18 in a pair. In this case, the shaft 14 may be fixed to the respective upper ends of the columns 18 in a pair and the wheel 22 may be rotationally supported on the shaft 14.
This invention is described as being applied to the pedal device with a single pedal. Alternatively, this invention may be applied to a pedal device with twin pedals.
Number | Date | Country | Kind |
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2014-230984 | Nov 2014 | JP | national |
Number | Name | Date | Kind |
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2027869 | La Londe | Jan 1936 | A |
6590147 | Kassabian | Jul 2003 | B2 |
7301088 | Chen | Nov 2007 | B2 |
7968781 | Luo | Jun 2011 | B1 |
20020056357 | Kassabian | May 2002 | A1 |
Number | Date | Country |
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2007-017805 | Jan 2007 | JP |