JP2011079113A - Device for mounting disc-shaped rotary tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for mounting a disc-shaped rotary tool in which the construction is simple and vibration thereof can be suppressed during use. <P>SOLUTION: The disc-shaped rotary tool (15) having a grinding surface (17) on an outer circumferential part thereof is provided with annular holding grooves (18) on an inner circumferential part thereof. The annular holding grooves (18) are fitted with exposed ring-shaped shock-absorbing bodies (30). A pair of holding bodies (20) are provided so as to face the both sides of the inner circumferential part of the disc-shaped rotary tool (15). The holding bodies (20) hold the both sides of the inner circumferential part of the disc-shaped rotary tool (15) through the shock-absorbing bodies (30) and the axial center part of the holding bodies (20) is fitted to an output shaft (11) of an electric motor (10) to fix integrally. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

 The present invention relates to a mounting device for a disk-shaped rotating tool that is mounted on an output shaft of an electric rotating machine by elastically holding a disk-shaped rotating tool such as a disk grindstone or a circular saw.

  There existed patent document 1 as a prior art. That is, as shown in FIG. 5, the inner flange 3, the buffer ring 4, the cup wheel 6, and the lock nut 7 are sequentially fitted to the drive shaft 2 of the electric rotating machine 1 from the outer end side. The buffer ring 4 is formed with an annular concave circumferential groove 4a at a portion facing the wheel body 6a of the cup wheel 6, and a ring-shaped cushion material 5 is fitted into the concave circumferential groove 4a. 6b is a grinding blade fixed to the outer peripheral portion of the outer surface (right surface) of the wheel body 6a.

  Then, the lock nut 7 is tightened to move the cup wheel 6 toward the inner flange 3 so that the back surface (left surface) of the wheel body 6a is brought into elastic contact with the cushion material 5.

  In the conventional device, vibration of the cup wheel 6 generated during use is buffered by the cushion material 5 and transmitted to the electric rotating machine 1 side, so that the burden on the user due to vibration is reduced. Become. However, since the concave circumferential groove 4a for holding the cushion material 5 is formed in the small buffer ring 4, it takes time to process the concave circumferential groove 4a, or the rigidity of the buffer ring 4 is increased by forming the concave circumferential groove 4a. Was reduced.

Japanese Patent No. 3032530

  SUMMARY OF THE INVENTION An object of the present invention is to provide a disk-shaped rotary tool mounting device that has a simple structure and can reduce vibration during use.

The present invention is configured as follows to achieve the above object. That is, according to the first aspect of the present invention, an annular holding groove is provided on at least the electric rotating machine side surface of the inner peripheral portion of the disk-shaped rotary tool having a grinding surface on the outer peripheral portion, and a ring-shaped buffer is provided in the holding groove. A body is exposed and fitted, and a pair of sandwiching bodies facing both sides of the inner periphery of the disk-shaped rotary tool is provided, and the inner periphery of the disk-shaped rotary tool is interposed by the sandwiching body through the buffer body. In addition to sandwiching both sides of the part, the shaft center part of the sandwiching body is fitted to the output shaft of the electric rotating machine and fixed integrally.
The invention according to claim 2 is configured such that an annular holding groove is formed by curving the inner peripheral portion of the disk-shaped rotary tool into a waveform.
According to a third aspect of the present invention, a seat surface that expands stepwise is provided at the base portion of the output shaft, and a screw shaft that protrudes outward from the shaft center portion of the seat surface is provided. An engaging portion that is threadedly engaged with the screw shaft and whose one end surface is in contact with the seating surface, and is fitted to the outer periphery of the base portion of the cylindrical portion so as to be relatively non-rotatable with the axial center portion of the disk-shaped rotary tool. A projection is provided, and an external thread is formed on the outer periphery of the end portion of the cylindrical portion, and the axial center portion of the other clamping body is screwed, and the axial length of the engagement projection is set in the axial direction of the inner peripheral portion of the disk-shaped rotary tool. The width is slightly larger than the width.

In the invention according to claim 1, since the holding groove for holding the buffer is formed on the inner peripheral portion of the disk-shaped rotary tool having a large diameter, the formation (processing) of the holding groove is facilitated. On the other hand, the accessory holding body for holding the disk-like rotary tool has a simple shape, which can be easily formed and the rigidity is not lowered.
In the invention according to claim 2, since the holding groove is formed by curving the inner peripheral portion of the disk-shaped rotary tool in a waveform, the rigidity of the inner peripheral portion of the disk-shaped rotary tool is increased. The holding groove can be formed quickly and with high accuracy by pressing.
According to a third aspect of the present invention, the disk-shaped rotary tool is fitted to the engagement protrusion of the cylindrical portion of one of the sandwiching bodies, and the buffer is fitted to the holding groove of the disk-shaped rotary tool. When the other holding body is screwed onto the male screw of the cylindrical portion, the disk-shaped rotating tool and each holding body become a unit in a state where the disk-shaped rotating tool is elastically pressed by the buffer body. For this reason, the disk-shaped rotary tool, the buffer body, and each sandwiching body can be assembled into a unit with high accuracy at the factory where the equipment is installed, and the unit can be quickly brought to the output shaft of the electric rotating machine by bringing it into the field. Can be attached with high accuracy.

It is sectional drawing which shows 1st Example of this invention. It is an expanded sectional view by the II-II line of FIG. It is a fragmentary sectional view showing the 2nd example of the present invention. It is a principal part expanded sectional view which shows 3rd Example of this invention. It is sectional drawing which shows a prior art example.

  Embodiments of the present invention will be described below with reference to the drawings. In FIG. 1, 10 is a case of an electric rotating machine (disc grinder), 11 is an output shaft for driving projecting outward (right) from the case 10, and a stepped seating surface 11a is formed at the base end. A small-diameter screw shaft 12 that is formed and protrudes rightward from the axial center portion of the seat surface 11a is formed.

  A disk-like rotary tool 15 such as a circular saw or a disc grindstone is attached to the output shaft 11 via a sandwiching body 20. The disk-shaped rotary tool 15 fixes super hard abrasive grains to the outer surface (right surface) of the outer peripheral portion of the substrate 16 formed of a steel plate, and this portion is used as a grinding surface 17. In addition, the inner peripheral portion of the substrate 16 is bent in a trapezoidal shape toward the inner side (left side), and the top surface, that is, the inner peripheral wall 16a is bent into a corrugated shape by a press machine and is held annularly on the left and right surfaces Grooves 18 (inner holding groove 18a and outer holding groove 18b) are formed. The holding groove 18 has a depth to which the ring-shaped buffer body 30 (30a, 30b) made of an O-ring is exposed and fitted.

  A spline-shaped center hole 19 (FIG. 2) is formed by punching a wall of an axial center portion located on the inner peripheral side of the holding groove 18. As shown in FIG. 3, the holding groove 18 is formed by bending the inner peripheral wall 16a of the substrate 16 at two predetermined intervals in the radial direction, a large-diameter inner holding groove 18a on the left side, and a small-diameter on the right side. The outer holding groove 18b may be formed.

  The sandwiching body 20 is made of metal and includes a stepped tubular outer sandwiching body (one sandwiching body) 21 and a disk-shaped inner sandwiching body (the other sandwiching body) 28. As shown in FIGS. 1 and 2, the outer sandwiching body 21 integrally has a cylindrical portion 23 that protrudes leftward from the axial center portion of the large-diameter collar portion 22. The flange portion 22 has a diameter that faces the outer surface (right surface) of the inner peripheral wall 16a of the substrate 16, and four operation holes 22a in which the operation tool is fitted and locked on the outer surface (right surface) side are formed in the circumferential direction. .

  A spline tooth-shaped engagement protrusion 24 is formed on the outer periphery of the base portion of the cylindrical portion 23 so as to be fitted and locked in the center hole 19 of the disk-like rotary tool 15 so as not to be relatively rotatable. The axial length of the engagement protrusion 24 is slightly larger than the axial width of the inner peripheral wall 16a of the disk-shaped rotary tool 15. Further, the outer periphery of the left end portion of the cylindrical portion 23 is stepped to have a small diameter, and a screw 25 is formed on the outer periphery of the small diameter portion.

  The inner clamping body 28 has a diameter that faces the inner surface (left surface) of the inner peripheral wall 16a of the substrate 16, and a female screw 28a that engages with the screw 25 of the outer clamping body 21 is formed at the axial center thereof. The two-chamfered tool engaging portion 28b with which a tool such as a spanner engages is formed on the left side.

  FIG. 4 shows a third embodiment. In FIG. 4, 16 is a board | substrate of the disk shaped rotary tool 15, 16a is the inner peripheral wall of the board | substrate 16, 21 is an outer clamping body, 28 is an inner clamping body. In the third embodiment, on the left surface of the inner peripheral wall 16a of the substrate 16, a part of the inner peripheral wall 16a is removed in a ring shape to form an inner holding groove 18a, and the left surface of the flange portion 22 of the outer sandwiching body 21 is formed. In addition, a part of meat of the flange portion 22 is removed in a ring shape to form an outer holding groove 22b, and the inner buffer body 30a is formed in the inner holding groove 18a and the outer buffer body 30b is formed in the outer holding groove 18b. To be exposed and fitted. The inner holding groove 18a and the outer holding groove 22b, and the inner buffer body 30a and the outer buffer body 30b have the same diameter.

  Next, the usage mode of the embodiment will be described. In FIG. 1 and FIG. 3, first, an inner buffer body 30a and an outer buffer body 30b made of O-rings are respectively formed in the left and right inner holding grooves 18a and outer holding grooves 18b formed on the inner peripheral wall 16a of the disk-shaped rotary tool 15. In this state, the center hole 19 of the disk-like rotary tool 15 is fitted to the engagement protrusion 24 of the outer sandwiching body 21. Next, the inner clamping body 28 is screwed into the external thread 25 of the outer clamping body 21, and the right surface (outer surface) of the inner clamping body 28 is pressed against the left surface of the engagement protrusion 24.

  In this case, the inner buffer body 30a and the outer buffer body 30b are pressed against the left and right surfaces of the inner peripheral wall 16a of the disk-shaped rotary tool 15 by the outer clamp body 21 and the inner clamp body 28, and elastically deform by a predetermined amount. In a state where the plate-like rotary tool 15 is clamped by the inner buffer body 30a and the outer buffer body 30b, the disk-like rotary tool 15 and the holding bodies 21 and 28 form a unit. Next, the cylindrical portion 23 of the outer clamping body 21 is screwed into the output shaft 11 of the electric rotating machine 10, and the left end surface thereof is brought into contact with the seating surface 11 a of the output shaft 11. Thereby, the disk-shaped rotary tool 15 can be quickly and accurately attached to the output shaft 11 of the electric rotating machine 10.

  In FIG. 4, the inner buffer body 30 a is fitted into the left inner holding groove 18 a formed on the inner peripheral wall 16 a of the disk-shaped rotary tool 15, and the outer formed on the left surface of the flange portion 22 of the outer holding body 21. The outer buffer bodies 30b are respectively exposed to the outer sides of the holding grooves 22b and fitted. In this state, the center hole 19 of the disk-shaped rotary tool 15 is fitted into the engaging protrusion 24 of the outer holding body 21, and then the inner holding body 28 is screwed into the screw 25 of the outer holding body 21, and the inner holding The right surface (outer surface) of the body 28 is pressed against the left surface of the engagement protrusion 24.

  In the same manner as described above, the disk-shaped rotary tool 15 and the holding bodies 21 and 28 become a unit in a state where the disk-shaped rotary tool 15 is clamped by the inner buffer body 30a and the outer buffer body 30b. Next, the cylindrical rotating tool 15 can be quickly and accurately attached to the output shaft 11 of the electric rotating machine 10 by screwing the cylindrical portion 23 of the outer holding body 21 into the output shaft 11 of the electric rotating machine 10. . In the present invention, in FIG. 1, the outer sandwiching body 21 and the inner sandwiching body 28 may be reversed left and right without inverting the disc-shaped rotary tool 15 left and right. Further, the buffer body 30 may be formed by omitting the outer buffer body 30b and only the inner buffer body 30a.

DESCRIPTION OF SYMBOLS 10 Electric rotating machine 11 Output shaft 11a Seat surface 12 Screw shaft 15 Disk-shaped rotary tool 16 Substrate 16a Inner peripheral wall 17 Grinding surface 18 Holding groove 18a Inner holding groove 18b Outer holding groove 19 Center hole 20 Holding body 21 Outer holding body (one side) Sandwiched body)
22 collar part 22a operation hole 23 cylinder part 24 engaging protrusion 25 external thread 28 inner clamping body (the other clamping body)
28a Female thread 28b Tool engagement part 30 Shock absorber (O-ring)
30a inner buffer 30b outer buffer

Claims (3)

  An annular holding groove (18) is provided at least on the surface on the electric rotating machine (10) side of the inner peripheral portion of the disk-shaped rotary tool (15) having a grinding surface (17) on the outer peripheral portion, and the holding groove (18). A ring-shaped shock absorber (30) is exposed and fitted to each other, and a pair of sandwiching bodies (20) facing both sides of the inner peripheral portion of the disk-shaped rotary tool (15) are provided, and the sandwiching bodies (20 ) To sandwich both sides of the inner peripheral portion of the disk-shaped rotary tool (15) via the buffer body (30), and the shaft center portion of the clamp body (20) is used as the output shaft of the electric rotating machine (10). (11) A disc-shaped rotating tool mounting device that is fitted and fixed integrally.   The disk-shaped rotary tool mounting device according to claim 1, wherein an annular holding groove (18) is formed by curving the inner peripheral portion of the disk-shaped rotary tool (15) into a waveform.   The base of the output shaft (11) is provided with a seating surface (11a) that expands stepwise, and a screw shaft (12) that protrudes outward from the axial center of the seating surface (11a) is provided to clamp one A cylindrical portion (23) is provided at the axial center portion of the body (21) so as to be screwed onto the screw shaft (12) and one end surface of which is in contact with the seat surface (11a). An engaging projection (24) that fits in a relatively non-rotatable manner is provided at the axial center of the disk-shaped rotary tool (15), and the axial center of the other clamping body (28) is provided on the outer periphery of the end of the cylindrical portion (23). A male screw (25) in which the portion is screwed is formed, and the axial length of the engaging protrusion (24) is slightly larger than the axial width of the inner peripheral portion of the disk-shaped rotary tool (15). A mounting device for a disk-shaped rotary tool according to claim 1 or 2.

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