JP2008044021A - Electrodeposited internal gear type grinding wheel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a grinding wheel of an electrodeposited internal gear type easy to temporarily fix and adjust, and as a result, to be mounted on a rotary mechanism of a grinding device in a short period of time, when mounting the grinding wheel of the electrodeposited internal gear type provided with a grinding part of gear type having an abrasive grain layer on which super abrasive grains are electrodeposited, is formed on the inner peripheral surface of a circular ring-like base metal. <P>SOLUTION: In the grinding wheel 1 of the electrodeposited internal gear type, a grinding part 3 of the gear type having an abrasive grain layer on which super abrasive grains are electrodeposited is formed on the inner peripheral surface of a circular ring-like base metal 2. The grinding wheel is characterized in that: a flange part 7 for fixing extending to the radial outer side of the circular ring formed by the base metal 2 is provided on one end surface side 6 of the base metal 2; and a mounting surface 7 perpendicular to the center axis of the base metal 2 is provided on the surface of the flange 7 on the other end surface side of the base metal 2. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electrodeposited internal gear type grindstone for grinding a tooth surface formed on the outer periphery of a gear serving as a workpiece.

  Conventionally, the central axis of the internal gear type grindstone in which the tooth mold for grinding the tooth surface formed on the outer periphery of the gear serving as the workpiece is formed on the inner tooth surface of the base metal, and the rotation axis of the rotating mechanism of the grinding device When the internal gear type grindstone attached to the grinding device is rotated around the rotation axis, the inner tooth surface is dressed by the dress gear, and the shape forming the inner tooth surface is a position around the rotation axis. The center axis and the rotation axis were made to coincide with each other by molding into the same shape.

  However, for example, in the case of the electrodeposited internal gear type grindstone described in Patent Document 1, hard abrasive grains containing hard CBN or the like are electrodeposited on the inner tooth surface of a substantially annular base metal that forms the inner teeth. Therefore, it is difficult to match the central axis of the electrodeposited internal gear type grindstone with the rotational axis of the grinding device by dressing the inner tooth surface and forming it into a predetermined size and shape.

Therefore, it is necessary to attach the central axis of the base metal having the inner tooth surface having a predetermined size and shape by electrodeposition of CBN abrasive grains so as to coincide with the rotational axis of the grinding apparatus. However, the base of the internal gear type grindstone is annular, and since the central axis is not formed on the base, it is not possible to provide an index for abutting the central axis with the rotation axis. It is very difficult to confirm whether or not the center axis of the grinding wheel coincides with the rotation axis. Therefore, for example, in order to confirm whether the central axis of the electrodeposition internal gear type grindstone and the rotation axis coincide with each other, a reference surface is provided on the base metal, and the reference surface is contacted by a tester to be used in the electrodeposition. The amount of run-out when the gear-type grindstone is rotated is detected, and the amount of run-out is used as a substitute characteristic for the amount of eccentricity between the center axis of the electrodeposited internal gear-type grindstone and the rotation axis. A technique for detecting the amount of eccentricity with respect to the rotation axis is disclosed (for example, see Patent Document 2).
JP-A-8-118145 Japanese Patent Laying-Open No. 2006-15416 (FIG. 4)

  However, in the case of detecting the amount of eccentricity between the center axis and the rotation axis by substituting the deflection amount described in Patent Document 2, in the installation and adjustment of the electrodeposition internal gear type grindstone, the electrodeposition internal gear It is necessary to adjust the center axis line and the rotation axis line by moving the electrodeposition internal gear type grindstone while rotating the mold grindstone while temporarily fixed to the rotating mechanism of the grinding apparatus.

  Conventionally, as shown in FIG. 5, the mounting structure of the grinding mechanism rotating mechanism and the electrodeposited internal gear type grindstone is provided in a mounting bracket 12 having a cylindrical inner peripheral surface 14 of the rotating mechanism 11 of the grinding apparatus. The base metal 2 of the electrodeposited internal gear-type grindstone 1 whose outer peripheral surface is cylindrical is inserted, one end face 6 of the base metal 2 is brought into contact with the collar 15, and the flange 17 is attached with a mounting bolt 19. The base metal 2 is attached to the mounting metal 12 by being fixed to the metal fitting 12, the collar 16 being brought into contact with the other end surface 9, and the flange 18 being fixed to the metal fitting 12 with an attachment bolt 19. ing.

Therefore, according to the conventional mounting structure, since the flange and collar are easily displaced from the electrodeposited internal gear type grindstone, skill is required to temporarily fix the electrodeposited internal gear type grindstone to the rotating mechanism of the grinding device. Moreover, there was a problem that it took time to install.
In addition, in order to place the grinding part at a predetermined position in the axial direction for each grinding wheel with different thickness, a color with a corresponding thickness is required, and a large number of parts are available corresponding to the number of types of grinding stones with different thicknesses. There was a problem that it was necessary to store it.

  The present invention has been made in consideration of such circumstances, and is a gear-type grinding part having an abrasive layer in which superabrasive grains such as CBN abrasive grains are electrodeposited on the inner peripheral surface of an annular base metal. When mounting the electrodeposited internal gear type grindstone formed with to the rotating mechanism of the grinding device, it is easy to temporarily fix and adjust. As a result, the electrodeposited internal gear type grindstone is attached to the rotating mechanism of the grinding device in a short time. An object of the present invention is to provide an electrodeposited internal gear type grindstone that can be used.

In order to achieve the above object, the present invention proposes the following means.
The invention described in claim 1 is an electrodeposited internal gear-type grindstone in which a gear-type grinding part having an abrasive grain layer electrodeposited with superabrasive grains is formed on the inner peripheral surface of an annular base metal. A fixing flange portion is formed on one end face side of the base metal and extends outward in the radial direction of the ring formed by the base metal, and the other of the base metal of the fixing flange portion is formed. A mounting surface perpendicular to the central axis of the base metal is formed on the surface on the end face side.

According to the electrodeposited internal gear type grindstone according to the present invention, the fixing flange portion extending radially outward of the ring formed by the base metal is formed on one end face side of the base metal. Since the mounting surface perpendicular to the central axis of the base metal is formed on the other end face side of the base metal, a flange or collar as a separate member is not required as in the prior art. By attaching the electrodeposition internal gear type grinding wheel to the grinding device with the mounting surface of the flange part in contact with the mounting portion of the grinding device, the electrodeposition internal gear type grinding wheel can be easily temporarily fixed and adjusted to the grinding device. It can be easily installed in a short time.
In addition, since the mounting surface of the fixing flange is brought into contact with the mounting portion of the grinding device, the electrodeposited internal gear wheel can be securely fixed so that it does not shift in the axial direction of the grinding device. It is possible to prevent quality defects caused by relative displacement between the internal gear wheel and the workpiece gear, and to form the tooth surface on the outer periphery of the gear to be a predetermined size and shape with high accuracy. It becomes possible.

Furthermore, according to the electrodeposition internal gear type grindstone according to the present invention, the mounting surface is a specific position of the base metal in the central axis direction, for example, the center of the grinding part in the width direction of the base metal along the axial direction. Or, it can be formed at a certain distance in the axial direction for each grindstone on the basis of any end face etc. of the grinding part, so when attaching the electrodeposition internal gear type grindstone to the grinder, Positioning in the axial direction of the electrodeposited internal gear type grindstone can be performed accurately and easily.
As a result, quality defects due to erroneous attachment of the relative positional relationship between the electrodeposition internal gear type grindstone and the gear serving as the workpiece can be prevented, and the tooth surface on the outer periphery of the gear serving as the workpiece has a predetermined dimension. It becomes possible to form the shape with high accuracy.

  The invention described in claim 2 is the electrodeposited internal gear type grindstone according to claim 1, wherein the base metal has a reference surface on a cylindrical inner peripheral surface centering on the central axis. It is formed.

  According to the electrodeposited internal gear type grindstone according to the present invention, as in Patent Document 2, the base metal has a reference surface formed on the inner peripheral surface of the cylindrical surface centered on the central axis. For example, by rotating the electrodeposited internal gear type grindstone while contacting a tester for vibration detection with this reference surface, the direction and runout of the eccentricity between the central axis and the rotation axis of the base metal of the electrodeposited internal gear type grindstone The amount can be easily detected.

  According to the electrodeposited internal gear type grindstone according to the present invention, it can be easily temporarily fixed and adjusted to the grinding device, and as a result, it can be attached in a short time. Further, the mounting surface of the fixing flange portion of the electrodeposited internal gear type grindstone can be mounted by contacting the mounting portion of the grinding device, so that it can be securely fixed and mounted on the grinding device.

FIG. 1 to FIG. 4 show an embodiment of an electrodeposited internal gear type grindstone of the present invention.
An electrodeposition internal gear type grindstone 1 of the present embodiment includes a base metal 2 formed in an annular shape around a central axis O using a metal material such as tool steel, and an inner peripheral surface of the base metal 2 A gear-type grinding part 3 is formed.

  As shown in FIG. 3, the grinding part 3 is formed with a plurality of tooth dies 4 which are uneven in the radial direction of the base metal 2 and extend in the central axis O direction in the circumferential direction on the inner peripheral surface of the base metal 2. An abrasive layer 5 in which superabrasive grains such as CBN abrasive grains and diamond abrasive grains are dispersed in a metal plating phase such as Ni and fixed by electrodeposition is formed on the surface. The tooth mold 4 in a state in which the gear 5 is formed meshes with the tooth surface on the outer periphery of the gear W to be ground by the electrodeposited internal gear wheel 1 so that the tooth surface of the gear W can be formed into a predetermined size and shape. Dimensions and shape.

The base metal 2 has, on one end face 6 side of the base metal 2, an annular plate-shaped fixing flange portion extending radially outward of the ring formed by the base metal 2 and centering on the central axis O 7 is integrally formed, and on the other end face 9 side (end face side opposite to the one end face 6 side) of the base metal 2 of the fixing flange portion 7, it is perpendicular to the central axis O of the base metal 2. 7A is formed over the entire surface of the other end face of the fixing flange portion 7.
The fixing flange portion 7 is formed with a plurality of through holes 7B at intervals in the circumferential direction of the flange portion 7, and mounting bolts 19 are inserted into the through holes 7B so that the mounting bracket of the rotating mechanism 11 is attached. The base metal 2 is attached to the rotation mechanism 11 by being screwed into the twelve screw holes.

  A reference surface 8 is formed on the inner peripheral surface of the base metal 2 around the central axis O of the electrodeposited internal gear type grindstone 1, and this reference surface 8 extends to one end surface 6 of the tooth mold 4. The reference surface 8 and the tooth mold 4 are connected by a bottom surface 8A formed perpendicular to the central axis O.

  In this embodiment, the mounting surface 7A of the fixing flange portion 7 rotates at the center of the width of the grinding portion 3 in the direction of the axis O of the base metal 2 when the base metal 2 is attached to the mounting bracket 12 of the rotating mechanism 11. The bottom surface 8 </ b> A in the direction of the axis O is formed closer to one end surface 6 side of the base metal 2 than the mounting surface 7 </ b> A of the fixing flange portion 7. ing.

The outer peripheral surface of the fixing flange portion 7 has a cylindrical surface centered on the central axis O, and has a larger outer diameter than the outer periphery of the cylindrical surface constituting the portion other than the fixing flange portion 7 of the base metal 2. is doing. Note that one end surface 6 and the other end surface 9 of the base metal 2 are planes perpendicular to the central axis O, like the above-described bottom surface 8A. Further, the depth of the reference surface 8 from the end surface 6 to the bottom surface 8A is formed smaller than the thickness of the flange portion 7 between the end surface 10 and the mounting surface 7A.
Moreover, the shape of the cross section including the central axis O of the base metal 2 in the portion from the fixing flange portion 7 and the grinding portion 3 to the fixing flange portion 7 is L-shaped as shown in FIG. The inner peripheral surface forming the reference surface 8 has a cylindrical shape centered on the central axis O, and the inner diameter, that is, the reference diameter D is larger than the root diameter d of the tooth mold 4 of the grinding part 3 and the base metal 2 The outer shape of the outer peripheral surface of the portion other than the fixing flange portion 7 is made smaller.

The electrodeposited internal grinding wheel 1 constructed in this way is attached to the rotating mechanism 11 of the grinding apparatus as shown in FIG. 4, and rotated around the rotation axis as shown in FIG. Grind the outer tooth surface.
Here, what is indicated by reference numeral 12 in FIG. 4 is a mounting bracket of the rotating mechanism 11 to which the electrodeposited internal gear wheel 1 is mounted. The mounting bracket 12 is a fixing flange portion 7 of the base metal 2. A cylindrical inner first peripheral surface 14 into which a portion other than the first inner peripheral surface 14 is inserted, and a cylindrical inner second inner peripheral surface 15 formed on one end surface 6 side of the first inner peripheral surface 14. The second inner peripheral surface 15 is formed to have a larger diameter than the first inner peripheral surface 14, and rotates to a portion that transitions from the second inner peripheral surface 15 to the first inner peripheral surface 14. It is an annular shape having a multi-stage hole in which a mounting portion 12A perpendicular to the rotation axis of the mechanism 11 is formed.

The mounting bracket 12 has its central axis O coincident with the rotational axis, and is supported by the grinding device via a bearing 13 with a crossing angle with the axis C of the gear W, and is rotated around the rotational axis by driving means (not shown). Is driven to rotate.
The electrodeposited internal gear-type grindstone 1 is detachably attached to the inner periphery of the mounting bracket 12 so that the center axis O is coaxial with the rotation axis.

  That is, the first inner peripheral surface 14 of the mounting bracket 12 has a cylindrical surface shape around the rotation axis having an inner diameter large enough to fit the outer periphery of the base metal 2 of the electrodeposited internal gear type grindstone 1. The base metal 2 of the electrodeposited internal gear wheel 1 is fitted into the first inner peripheral surface 14 of the mounting bracket 12. At this time, the portion of the fixing flange portion 7 is inserted into the second inner peripheral surface 15.

  Thus, after the electrodeposition internal gear type grindstone 1 is fitted into the mounting bracket 12, the first inner peripheral surface 14 of the mounting bracket 12 is equal to the outer diameter of the base metal 2 on the end face 9 side. A ring-shaped collar 16 having a square cross section having an outer diameter and an inner diameter larger than the reference diameter D is inserted and the end face of the mounting bracket 12 connected to the first inner peripheral surface 14 to fix the collar 16. An annular flange 18 having an inner diameter smaller than the inner diameter of the first inner peripheral surface 14 and larger than the inner diameter of the collar 16 is attached to 12B around the rotation axis.

A plurality of mounting bolts 19 are inserted into the flange 18, and when these mounting bolts 19 are screwed into the end surface 12 </ b> B of the mounting bracket 12, the inner peripheral portion of the flange 18 is the first inner periphery of the mounting bracket 12. It is attached in a state of protruding to the inner peripheral side from the surface 14.
The flange 18 has a substantially L-shaped cross section in which an outer peripheral portion thereof is fitted and inserted into the first inner peripheral surface 14 of the mounting bracket 12 and protrudes to one side. Further, the end face 18 </ b> A protruding to the inner peripheral side is a plane perpendicular to the rotation axis of the rotation mechanism 11 when attached to the end face 12 </ b> B of the mounting bracket 12.

In the electrodeposited internal gear type grindstone 1, the fixing flange portion 7 is inserted into the second inner peripheral surface 15 by inserting the cylindrical outer peripheral surface of the base metal 2 into the first inner peripheral surface 14. At the same time, the mounting surface 7A is brought into contact with the mounting portion 12A so as to be mounted on the mounting bracket 12.
In this way, the mounting surface 7A of the fixing flange portion 7 is brought into contact with the mounting portion 12A connected to the second inner peripheral surface 15, and a plurality of mounting bolts 19 are inserted into the fixing flange portion 7, and these mounting bolts By screwing 19 into the mounting bracket 12, the electrodeposited internal gear wheel 1 is attached to the mounting bracket 12.

A method for attaching the electrodeposition internal gear type grindstone 1 thus configured to the rotating mechanism 11 of the grinding apparatus will be described.
The electrodeposition internal gear type grindstone 1 is configured as shown in FIG. 4, in a state where it is temporarily fixed to the mounting bracket 12, a tester 20 for shake detection is brought into contact with the reference surface 8, and the electrodeposition internal gear While the mold grindstone 1 is rotated around the rotation axis, the deflection of the reference surface 8 relative to the rotation axis is detected.
The shake of the reference surface 8 by the tester 20 is detected as shown in FIG. When shake is detected, the gear W shown in FIG. 1 is not arranged.

  The tester 20 is fixed on the machine of the grinding apparatus separated from the rotation mechanism 11, and the tip is urged toward the radial outer side of the electrodeposited internal gear type grindstone 1 to be in contact with the reference surface 8. A contact terminal 20A is provided, and the variation of the contact position of the contact terminal 20A can be detected by, for example, a meter reading 20B provided in the tester 20.

  According to the electrodeposited internal gear type grindstone 1 according to the above embodiment, the electrodeposited internal gear type grindstone 1 is inserted into the mounting bracket 12, and the mounting surface 7A of the fixing flange portion 7 is brought into contact with the mounting portion 12A. Since the electrodeposition internal gear type grindstone 1 is temporarily fixed to the mounting bracket 12 and the runout adjustment is performed by the mounting bolt 19 in a state of being mounted, it is easy to temporarily fix and run out the electrodeposition internal gear type grindstone 1 to the mounting bracket 12. After adjusting the eccentricity between the central axis O and the rotation axis, the electrodeposited internal gear-type grindstone 1 can be easily and securely attached to the rotating mechanism 11, and as a result, the electrodeposited internal gear-type grindstone 1. Can be easily attached to the rotating mechanism 11 in a short time.

According to the electrodeposited internal gear type grindstone 1 according to the above embodiment, the outer periphery of the base metal 2 of the electrodeposited internal gear type grindstone 1 is fitted and fixed to the first inner peripheral surface 14 of the mounting bracket 12. Since the mounting surface 7A of the flange portion 7 is fixed in contact with the mounting portion 12A, the electrodeposited internal gear wheel 1 can be securely fixed to the mounting bracket 12 both in the radial direction and in the axial direction. it can.
Therefore, this electrodeposition internal gear type grindstone 1 is restrained from being displaced relative to the rotation mechanism 11, and quality defects caused by the electrodeposition internal gear type grindstone 1 and the gear W being relatively displaced are suppressed. The gear W having a predetermined size and shape of the gear W can be reliably manufactured.

Moreover, according to the electrodeposition internal gear type grindstone 1 according to the above embodiment, when the attachment surface 7A of the fixing flange portion 7 attaches the base metal 2 to the mounting bracket 12 of the rotating mechanism 11, the base metal 2 Since the center of the width of the grinding part 3 in the direction of the axis O is formed at a position that substantially coincides with the center of the width of the rotating mechanism 11, the electrodeposited internal gear type grindstone 1 is attached to the grinding device via the mounting bracket 12. The center of the grinding part 3 and the center of the rotation mechanism 11 in the direction of the axis O of the base metal 2 can be accurately and easily matched.
As a result, it is possible to easily and reliably prevent a quality defect on the outer peripheral tooth surface of the gear W caused by erroneously attaching the position in the axis O direction with respect to the mounting bracket 12 of the electrodeposited internal gear wheel 1.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention. For example, in the above embodiment, The mounting surface 7 has been described with respect to the case where the entire surface is formed perpendicular to the central axis O, but the mounting surface 7A may be formed on a part of the other end surface side of the fixing flange portion 7. Good.

In addition to the mounting surface 7 </ b> A of the fixed flange portion 7, the electrodeposited internal gear-type grindstone 1 of the above embodiment includes a reference surface 8 that detects a deflection of the central axis O of the base metal 2 with respect to the rotation axis of the rotation mechanism 11. Although the case has been described, it is also possible to adopt a configuration in which only the attachment surface 7 is provided and the reference surface 8 is not provided.
Moreover, although the case where the mounting surface 7A of the fixing flange portion 7 is formed on one end surface side with respect to the bottom surface 8A of the reference surface 8 of the base metal 2 has been described, the bottom surface 8A of the reference surface 8 is the mounting surface 7A. Alternatively, it may be formed on one end face 6 side.

  Further, when the mounting surface 7 </ b> A attaches the base metal 2 to the mounting bracket 12 of the rotating mechanism 11, the center of the width of the grinding portion 3 in the axis O direction of the base metal 2 substantially coincides with the center of the width of the rotating mechanism 11. Although the case where it is formed at the position has been described, the attachment surface 7 </ b> A may be formed so that the center of the width of the grinding portion 3 is located at a portion other than the center of the width of the rotation mechanism 11.

It is a perspective view which shows one Embodiment of the electrodeposition internal gear type grindstone of this invention. It is a fragmentary sectional view in alignment with the central axis O of the electrodeposition internal gear type grindstone 1 of embodiment shown in FIG. It is ZZ sectional drawing in FIG. It is a fragmentary sectional view along the central axis O of the rotation mechanism 11 which attached the electrodeposition internal gear type grindstone 1 of embodiment shown in FIG. It is a figure which shows the conventional attachment with respect to the rotation mechanism of an electrodeposition internal gear type grindstone.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electrodeposited internal gear type grindstone 2 Base metal 3 Grinding part 5 Abrasive layer 6 One end surface of base metal 2 7 Flange part 8 Reference surface 9 The other end surface of base metal 2 Rotating mechanism 12 Mounting bracket 14 Mounting bracket 12 First inner peripheral surface 15 Second inner peripheral surface 16 of mounting bracket 12 Collar 18 Flange 19 Mounting bolt 20 Tester 20 A for detecting vibration Contact terminal O Center axis W of base metal 2 Gear (work)
C Gear W axis

Claims (2)

An electrodeposited internal gear-type grindstone in which a gear-type grinding part having an abrasive grain layer electrodeposited with superabrasive grains is formed on the inner peripheral surface of an annular base metal,
On one end face side of the base metal, a fixing flange portion extending radially outward of the ring formed by the base metal is formed,
An electrodeposition internal gear-type grindstone characterized in that a mounting surface perpendicular to the central axis of the base metal is formed on the surface of the fixing flange portion on the other end face side of the base metal. 2. The electrodeposited internal gear type grindstone according to claim 1, wherein the base metal has a reference surface formed on a cylindrical inner peripheral surface centering on the central axis. 3.

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