JPH07208554A - Flywheel device - Google Patents

Abstract

PURPOSE:To reduce noise by suppressing the air cut noise generated from a tapped hole or through hole, in the revolution of a fixed flywheel and a variable flywheel. CONSTITUTION:An annular groove 12A is formed on a fixed flywheel 12, and a cover plate 18 is fitted in the annular groove 12A, and the tapped holes 12B, 12B,... formed on the fixed flywheel 12 are closed. Further, annular grooves 14B and 16B are formed on the variable flywheels 14 and 16, and since the cover plate 18 is fitted into the annular grooves 14B and 16B, the through holes 14C formed on the variable flywheels 14 and 16 are closed. Accordingly, when the fixed flywheel 12 and variable flywheels 14 and 16 revolve, the air cut noise generated form the tapper hole 12B and the through hole 14C can be suppressed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flywheel device, and more particularly to a flywheel device that applies a moment of inertia to a rotating shaft.

[0002]

2. Description of the Related Art A flywheel device is used for the purpose of imparting a moment of inertia to a shaft so as to keep the rotation of the shaft constant. This flywheel device has a fixed flywheel and a variable flywheel,
The fixed flywheel is fixed to the shaft, and the variable flywheel is detachably attached to the fixed flywheel. Then, by attaching and detaching the variable flywheel, the magnitude of the moment of inertia can be adjusted.

[0003]

In this case, since the variable flywheel is mounted on the fixed flywheel via the mounting bolts, the fixed flywheel is formed with a screw on its side portion for screwing the mounting bolts. . Also, the variable flywheel is formed with a through hole for passing through the mounting bolt. Therefore, for example, when rotating with only the fixed flywheel or when attaching the variable flywheel to the fixed flywheel and rotating, wind noise is generated from the screw holes of the fixed flywheel and the through holes of the variable flywheel, and noise is generated. There is the problem of becoming expensive. Therefore, an object of the present invention is to provide a flywheel device that solves the problems of the above-mentioned conventional techniques and that can prevent wind noise and reduce noise.

[0004]

In order to achieve the above object, the present invention adjusts the magnitude of the fixed flywheel that gives a moment of inertia for maintaining a constant rotation speed of the shaft. In order to achieve this, in a flywheel device including a variable flywheel detachably attachable to a side portion of the fixed flywheel via an attachment bolt, a screw hole into which the attachment bolt is screwed is provided on a side of the fixed flywheel. Part of the fixed flywheel is covered with a ring-shaped cover member that fits into a first annular groove formed on the side of the fixed flywheel, and the through hole through which the mounting bolt penetrates is the screw hole. Formed on the side of the variable flywheel facing the
The first through hole is covered with the ring-shaped cover member fitted in a second annular groove formed in a side portion of the variable flywheel.

[0005]

According to the present invention, since the fixed flywheel is formed with the first annular groove and the ring member is fitted in the first annular groove, the screw hole formed in the fixed flywheel is closed. . In addition, since the second annular groove is formed in the variable flywheel and the ring member is fitted in the second annular groove, the through hole formed in the variable flywheel is closed.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a flywheel device according to the present invention will be described below with reference to the drawings. In FIG. 1, a flywheel device generally designated by reference numeral 10 includes a fixed flywheel 12, variable flywheels 14 and 16, and cover plates (cover members) 18 and 18. The fixed flywheel 12 is formed in a substantially disc shape, and a shaft 20 is coaxially and integrally fixed to an opening hole in the center. Both ends of the shaft 20 are rotatably supported by support bases 24, 24 via ball bearings 22, 22, and the support bases 24, 24 are fixed to a mount 26.

As a result, the fixed flywheel 12 rotates integrally with the shaft 20 and applies a moment of inertia to the shaft 20. In addition, annular grooves (first annular grooves) 12A, 12 are provided on the left and right side portions of the fixed flywheel 12, respectively.
A is formed concentrically, and the screw hole 12 is formed in the annular groove 12A.
B, 12B, ... Are formed concentrically. Screw hole 1
Mounting bolts 28, which will be described later, are screwed to 2B, 12B, .... Further, annular recesses 12B and 12B are formed on the left and right side portions of the fixed flywheel 12, respectively.
F and 16F are fitted.

The variable flywheel 14 is attached to the right side of the fixed flywheel 12 in FIG. The variable flywheel 14 is formed in a disk shape, and the shaft 20 penetrates the central opening hole 14A. An annular groove (second annular groove) is provided on the right side of the variable flywheel 14.
14B (see FIG. 2) is formed. The annular groove 14B is formed in the same manner as the annular groove 12A, and through holes 14C, 14C ... Are formed concentrically in the annular groove 14B at intervals of 90 degrees. The mounting bolt 28 described above is fitted into the through hole 14C, and a counterbore portion into which the head of the mounting bolt 28 is fitted is formed in the through hole 14C. The mounting bolts 28, 28 ... Fit into the through holes 14C, 14C ... Are screwed into the screw holes 12B, 12B ,.
The variable flywheel 14 is fixed to the right side portion of the fixed flywheel 12.

Further, the through hole 14 is provided in the annular groove 14B.
Screw holes 14 are formed on the concentric circles where C, 14C ...
D, 14D ... Are formed. When a bolt (not shown) is screwed into the screw hole 14D and the bolt is projected from the variable flywheel 14, the variable flywheel 14 is removed from the fixed flywheel 12. Also, the annular groove 1
In 4B, screw holes 14E, 14E ... Are formed on concentric circles having through holes 14C, 14C.
A screw 30 described later is screwed to E. The above-mentioned protruding portion 14F is formed in an annular shape on the left side portion of the variable flywheel 14, and the protruding portion 14F is fitted into the fitting groove 12B.

As shown in FIG. 2, the cover plate 18 is formed in an annular shape, and the cover plate 18 is fitted in the annular groove 14B. The cover plate 18 has holes 18A, 18A, ...
Are formed on concentric circles at intervals of 90 degrees. Hole 18A
A screw 30 is fitted in the screw 30, and the screw 30 is screwed into the screw hole 14E. As a result, the cover plate 18 in the annular groove 14B is fixed via the screws 30, 30 ..., and the through holes 14C, 14C ... And the screw holes 14D, 14D. ing.

Like the variable flywheel 14, the variable flywheel 16 is attached to the left side portion of the fixed flywheel 12 via mounting bolts 28, 28 ... Like the variable flywheel 14, the variable flywheel 16 is formed with an annular groove 16B, a through hole (not shown), and screw holes 16D, 16D. In this case, the annular groove 16B corresponds to the annular groove 14B, and the through hole corresponds to the through hole 14C. Also, the screw hole 16D is the screw hole 1
Corresponds to 4D. A cover plate 18 is fitted in the annular groove 16B of the variable flywheel 16, and the cover plate 18 is fixed via screws 30, 30 ...
Therefore, the through hole of the variable flywheel 16 and the screw hole 1
6D, 16D ... Are closed by a cover plate 18.

Next, the operation of the flywheel device according to the present invention constructed as above will be described. When the shaft 20 is rotated, the fixed flywheel 12 and the variable flywheels 14 and 16 rotate together with the shaft 20. As a result, a moment of inertia is generated in the fixed flywheel 12 and the variable flywheels 14 and 16, and the rotation of the shaft 20 is maintained constant. A cover plate 18 is fitted into the annular grooves 14B and 16B of the variable flywheels 14 and 16, and the cover plate 18 has through holes 14C, 14C ... And screw holes 14D, 14D ... Inside the annular groove 14B.
Or through holes in the annular groove 16B and screw holes 16D, 16D
... is blocking. Therefore, the variable flywheels 14, 1
Even if 6 rotates, the through holes 14C, 14 in the annular groove 14B
Wind noise is not generated from C ... and screw holes 14D, 14D ..., or through holes and screw holes 16D, 16D ... In the annular groove 16B.

Although the variable flywheels 14 and 16 are attached to the fixed flywheel 12 in the above embodiment, the present invention is not limited to this, and it is also possible to use only the fixed flywheel 12 as shown in FIG. is there. In this case, the cover plates 18, 18 are fitted in the annular grooves 12A, 12A formed in the fixed flywheel 12, respectively. In the annular groove 12A, the same screw holes (not shown) as the screw holes 14E, 14E ... Formed in the annular groove 14B are formed, and a screw 3 is formed in this screw hole.
The cover plate 18 is fixed in the annular groove 12A by screwing 0, 30 ... Thereby, the annular groove 12
Screw holes 12B, 12B, ... Inside A and 12A are cover plates 1
Since it is closed by 8, the wind noise does not occur from the screw holes 12B, 12B, ... Even if the fixed flywheel 12 rotates.

[0014]

As is apparent from the above description, according to the flywheel device of the present invention, the fixed flywheel is formed with the first annular groove, and the ring member is fitted into the first annular groove. Therefore, the screw hole formed in the fixed flywheel is closed. In addition, since the second annular groove is formed in the variable flywheel and the ring member is fitted in the second annular groove, the through hole formed in the variable flywheel is closed. As a result, when the fixed flywheel and the variable flywheel rotate, the wind noise generated from the screw holes and the through holes can be eliminated, and noise can be reduced.

[Brief description of drawings]

FIG. 1 is a vertical sectional view showing an embodiment of a flywheel device according to the present invention.

FIG. 2 is an enlarged perspective view showing a main part of a flywheel device according to the present invention.

FIG. 3 is a transverse cross-sectional view taken along the line AA of FIG.

FIG. 4 is a side sectional view as seen from the direction of arrow BB in FIG.

FIG. 5 is a longitudinal sectional view showing another embodiment of the flywheel device according to the present invention.

[Explanation of symbols]

 10 Flywheel device 12 Fixed flywheel 12A, 14B, 16B Annular groove 12B Screw hole 14, 16 Variable flywheel 14C Through hole 18 Cover member 20 Shaft 28 Mounting bolt

Claims (1)

[Claims] 1. A fixed flywheel that applies a moment of inertia for maintaining a constant rotation speed of a shaft, and a mounting bolt on a side portion of the fixed flywheel for adjusting the magnitude of the moment of inertia. In a flywheel device including a variable flywheel detachably attachable, a screw hole into which the mounting bolt is screwed is formed on a side portion of the fixed flywheel, and the screw hole is formed on a side of the fixed flywheel. Is covered with a ring-shaped cover member that fits into a first annular groove formed in the portion, and a through hole through which the mounting bolt penetrates is formed in a side portion of the variable flywheel facing the screw hole. The through hole is covered with the ring-shaped cover member that fits in a second annular groove formed in a side portion of the variable flywheel. And flywheel device.