JP2015229214A - Honing processing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a honing processing device which can precisely supply a next grind stone to the same position when a grind stone rotationally supported is worn out.SOLUTION: Driving means M1 of a grind stone rotation mechanism is arranged in an upper portion of a turret rotation disk 4, and includes joint release means which joins and releases a plurality of grind stone rotation shafts. The grind stone rotation shafts are switched and driven through the joint release means to change and use four grind stones T while rotating them.

Description

  The present invention relates to a honing apparatus for honing a curved surface or a spherical surface of a workpiece.

  A ball valve, a ball joint, an artificial joint, and the like are provided with an outer sphere work (convex sphere member) and an inner sphere work (concave sphere member) as mechanical kinematic pairs that move in contact with each other. The outer sphere part (convex sphere part) and inner sphere part (concave sphere part) are made of high-strength metals such as iron, stainless steel, nickel, chromium, titanium, their alloys or hard ceramics, and are polished using a grindstone. doing. In order to obtain smooth slidability, it is necessary to increase the true sphericity of the spherical surface of the workpiece, which has been a manual work in the past.

  With the advancement of machine tools, honing processing apparatuses for honing a spherical surface of a work by contacting a work while rotating a grindstone have been studied and put into practical use.

  Patent Document 1 relates to a honing method, in which a spherical workpiece is provided at the tip of a rotating shaft whose base end is rotatably supported, and a cup-type grindstone that fits the spherical surface of a pair of rotating spherical workpieces is a spherical surface. A honing method in which the surface of the spherical workpiece is swung around the center of the spherical body of the workpiece and is rotated by a rotation axis passing through the center of the spherical body, wherein the grinding stone is intermediate When positioned at a point, the rotation axis of the spherical workpiece and the two rotation axes of the grindstone are in the same plane, and both the rotation axes of the grindstone and the rotation axis of the spherical workpiece from the spherical body center to the tip A pair of grindstones are arranged so as to be inclined so that the angle formed by the two rotation axes of the grindstone is the same acute angle with each other, the spherical workpiece is rotated, and the two grindstones are the same Rotate in the direction and move both wheels simultaneously Or one of the grinding wheel in pressure contact with the spherical body workpiece alternately processing the processing surface of the spherical body workpieces (Part claim 1), is described.

  Patent Document 2 relates to a spherical grinding device for a lens, a Z-axis servomotor that moves the workpiece axis in the axial direction, a control device for the output torque of the Z-axis servomotor, a B-axis servomotor that swings a swing table, An X moving table that reciprocates in a direction crossing the workpiece axis along a guide provided on the swing table, an X axis servo motor that drives the X moving table, and the guide on the X moving table. And two of the grindstone shafts mounted in an orthogonal direction, and one of the two grindstone shafts is inclined at a predetermined angle with respect to the workpiece shaft at a position passing through the rocking center of the rocking table. The other of the two grindstone shafts is rotated in a state where the distance from the rocking center to the center of curvature of the lens to be processed is d, and the axis is perpendicular to the axis where the axis passes through the rocking center. Between the movement amount x and the inclination angle θ with respect to the workpiece axis Rotating while maintaining the relationship of x = dtanθ (Part claim 1), it is described.

  Patent Document 3 relates to a spherical processing machine that processes a workpiece into a spherical surface, and has a grinding tool for grinding so that a spherical surface is formed on the workpiece, and rotates the grinding tool to the workpiece rotated by the workpiece rotating device. A grinding unit that can be pressed while rotating, and a polishing tool for polishing the surface of the workpiece formed on the spherical surface, and pressing while rotating the polishing tool against the workpiece rotated by the workpiece rotating device A polishing unit capable of rotating the grinding tool, and a position where the grinding tool can contact the workpiece rotated by the workpiece rotating device. And a grinding tool moving device for moving the grinding tool rotating device between a position retracted from the grinding tool rotating device, and the polishing unit comprises the polishing unit. A polishing tool rotating device for rotating a tool, and a polishing tool movement for moving the polishing tool rotating device between a position where the polishing tool can come into contact with the work rotated by the work rotating device and a position retracted therefrom. Having a device (claim 2 thereof).

  Patent Document 4 relates to a honing tool, and includes a mandrel main body attached to a main shaft such as a honing machine, a grindstone base having a grindstone capable of moving back and forth in the radial direction of the mandrel main body, and a wedge for moving the grindstone base forward and backward. The mandrel main body is a small diameter portion having an outer diameter corresponding to the machining diameter at the distal end side, and a large diameter portion having an outer diameter larger than the small diameter portion at the proximal end side. In addition, a guide groove is provided extending in the axial direction, and in the guide groove, the whetstone base is provided so as to be able to advance and retreat in the radial direction, and the wedge is provided so as to be able to advance and retreat in the axial direction. The long mandrel body extends from the small-diameter portion to the large-diameter portion, the front end side outer diameter is provided with the grindstone, and the inner diameter is provided with a pair of front and rear driven cam surfaces, The edge is a long one extending from the small-diameter portion to the large-diameter portion of the mandrel body, and a pair of front and rear drive cam surfaces cooperating with the driven cam surface are provided on the outer diameter thereof. The drive cam surface and the driven cam surface Are inclined surfaces inclined at the same angle, so that when the wedge is in the forwardly advanced position or the backwardly retracted position, the grindstone protrudes radially outward from the small diameter portion of the mandrel body, while the wedge When the wheel is in the backward retracted position or forwardly advanced position, the grindstone is retracted into the small diameter portion (the claim 1), and an annular groove is provided at the front and rear positions of the large diameter portion of the mandrel body. In addition, an elastic ring member is fitted in the annular groove, and the grindstone base is always urged radially inward by the elastic force of the elastic ring member (the third aspect thereof), It has been described.

  Patent Document 5 relates to a honing machine having a grindstone diameter expansion / contraction means for changing a grindstone diameter, a spindle of a machine tool on which a tool is detachably mounted, and a reference value in which a machining amount of a workpiece by the tool is set in advance. A machining amount measuring means for measuring based on the comparison, a reference value setting member for setting the reference value for the tool in a state where the tool is stored, a tool and the replacement tool are stored in the tool In a processing apparatus provided with an automatic tool changer that changes a tool mounted on a spindle by conveying it to and from a tool storage position, the reference value setting member is installed at the tool storage position, and the reference value The automatic tool changer is configured to convey a tool stored in a setting member to the spindle (claim 1), and a tool mounted on the honing machine is used as the machining amount measuring means. A reference value setting member, comprising: a dimension measuring air supply means for injecting air for hole diameter dimension measurement; and a dimension detecting means for detecting the air pressure to obtain the hole diameter dimension of the hole into which the tool is inserted. And a reference pressure setting air supply means for injecting air into the mastering from the tool stored in the mastering. (Claim 4).

Japanese Patent Publication No. 8-5002 JP 2006-297520 A JP 2010-115749 A Japanese Patent Publication No. 7-10493 JP-A-5-318255

  As described above, the workpiece is made of a high-strength metal, an alloy thereof, hard ceramics, or the like, and when polishing is performed using a grindstone, the polishing operation is often interrupted due to wear of the grindstone. However, in the apparatuses described in Patent Documents 1 to 4, when the grindstone is worn, the polishing operation is interrupted, and the operating rate is reduced due to the grindstone replacement. In the apparatus described in Patent Document 5, when a grindstone is worn, a replacement tool is taken out from a magazine in which a replacement tool is stored and automatically replaced, so that a large-scale apparatus configuration is formed. As a result, the polishing operation is interrupted.

  Accordingly, an object of the present invention is to supply the next grindstone accurately to the same position immediately when the grindstone wears against the grindstone that is rotatably supported, and to efficiently process the curved surface and spherical surface of the workpiece. An object of the present invention is to provide a honing apparatus capable of performing the same.

The present invention includes a workpiece rotating mechanism that rotates a workpiece and a grindstone rotating mechanism that rotates a grindstone. In a honing apparatus that processes a curved surface or a spherical surface of a workpiece, the grindstone rotating mechanism includes a plurality of grindstones arranged on an outer periphery. A turret rotating disk and a driving means for rotating the turret rotating disk, and one driving means for the grindstone rotating mechanism is arranged on the turret rotating disk, and the connection release for releasing the connection between the plurality of grindstone rotating shafts and the turret driving means. Means for switching and driving the grindstone rotating shaft via the connection releasing means.
According to the present invention, a grindstone rotating shaft that rotates a plurality of grindstones via a disengaging means by one turret driving means is disengaged from the shaft of the driving means, and the grindstone is rotated by one grindstone driving means. it can.

The present invention also includes a workpiece rotating mechanism that rotates a workpiece and a grindstone rotating mechanism that rotates a grindstone. In the honing apparatus that processes a curved surface or a spherical surface of the workpiece, the grindstone rotating mechanism includes a plurality of grindstones on the outer periphery. The turret rotating disk and the turret driving means for rotating the turret rotating disk are provided. When one grindstone is worn, the turret rotating disk is rotated to use the next grindstone and / or by the work rotating mechanism. It is characterized in that it comprises a left and right swing mechanism for swinging the turret turntable with respect to the supported work in the direction opposite to the rotation direction.
According to the present invention, the turret rotating disk can be rotated and the grindstone at the tip of each turret can be replaced and used. Therefore, even if one grindstone is worn, the turret rotating disk is rotated and the workpiece is moved by another grindstone. Can be processed. Since the workpiece can be machined by rotating the turret and performing a horizontal swinging operation in the horizontal direction using the rotating mechanism of the turret board, machining by efficient movement is possible. .

The present invention is characterized in that the plurality of grindstones of the turret rotating disk are provided with a grindstone for machining the inner curved surface and the inner spherical surface of the workpiece and a grindstone for machining the inner curved surface and the outer spherical surface of the workpiece. .
According to the present invention, when processing the inner curved surface and inner spherical surface of the workpiece and processing the outer curved surface and outer spherical surface of the workpiece, the corresponding inner processing grindstone and outer processing grindstone can be exchanged and processed, Continuous processing can be performed efficiently.

According to the present invention, the work rotation mechanism includes a vertical swing mechanism that swings the work up and down and a left-right swing mechanism that swings left and right. The workpiece rotating mechanism includes a vertical swing mechanism that swings the workpiece up and down, and the grindstone rotating mechanism includes a left-right swing mechanism that swings left and right relative to a horizontally supported workpiece. .
According to these aspects of the present invention, the combination of the vertical swing mechanism and the left / right swing mechanism increases the processing range for the outer curved surface / outer spherical surface and the inner curved surface / outer spherical surface of the workpiece, enabling high-precision machining. It becomes possible.

  According to the present invention, the grindstone rotating mechanism rotates the turret rotating disk on which a plurality of grindstones are arranged, and the turret rotating disk. Can be accurately supplied to the same position. In addition, since the left and right swing mechanism and the vertical swing mechanism that swing left and right with respect to the workpiece are provided using the rotation mechanism of the turret board, the curved surface and spherical surface of the workpiece can be efficiently processed. .

It is a side view of the honing processing apparatus of one embodiment of this invention. It is a side view of the said embodiment. It is a perspective view of the principal part of the said embodiment. It is a figure of the turret rotation part of the said embodiment, The (a) is sectional drawing, The (b) is the AA line cross section of (a). It is sectional drawing of the turret rotary disk of the said embodiment. It is an operation | movement figure of the up-and-down swing mechanism of the workpiece | work rotation mechanism of the said embodiment. It is a side view of the workpiece | work rotation mechanism of the said embodiment. It is an operation | movement figure of the left-right rocking | fluctuation mechanism of the said embodiment. It is a figure explaining the example of a process of the workpiece | work of the said embodiment. It is an operation | movement figure of the drive mechanism of the said embodiment. It is an operation | movement figure of the drive mechanism of the said embodiment.

  The honing apparatus 1 according to the present embodiment includes a workpiece rotation mechanism 2 that grips and rotates a workpiece and a grindstone rotation mechanism 11 that rotates and processes the workpiece W on a base 10. 1 is a honing apparatus 1 that performs machining and machining of an inner curved surface of a workpiece. These controls are controlled by the control panel 17 of the base 10. The workpiece rotating mechanism 2 and the grindstone rotating mechanism 11 are configured to perform a machining operation on the central axis 2a on the base 10, and both the workpiece rotating mechanism 2 and the grindstone rotating mechanism 11 operate toward the central axis 2a. Do. A separator for supplying the coolant C1 is disposed on the outer periphery near the base 10.

  The work rotation mechanism 12 includes a mechanism S1 that rotates the vertical axis 3 while chucking the work W while rotating the work W. The vertical swing mechanism S1 is disposed on a vertical plate 14 erected on the base 10 (FIGS. 6 and 7). That is, the rack 6a of the rack and pinion mechanisms 6a and 6b is arranged in an R shape in the vertical direction above the vertical plate 14, and a vertical movement driving means (motor) M4 for driving the rack and pinion mechanisms 6a and 6b is provided. It is attached and has a structure that moves up and down along the R-shaped rail and groove. The vertical plate 14 is provided with a gripping mechanism (chuck) 8 that grips and rotates the rotating shaft 4 that rotates the workpiece W, and a rack 15 b (R-shaped pinion) that drives the gripping mechanism 8. A driving means M4 for rotating the rotating disk 4 in the vertical direction is attached to the vertical plate 14 above the rotating disk 4. Reference numeral Rg in FIG. 6 is a reinforcing guide (R-shaped guide), which assists the rack and pinion mechanisms 6a and 6b. It is also possible to drive along the groove Rm instead of the rail structure (FIG. 3). Accordingly, when the workpiece rotating mechanism 12 that is moved up and down by the rack and pinion mechanisms 6a and 6b is mounted on the R-shaped guide 6a and the R-shaped rack 6a is driven in conjunction with the pinion 6b, the spindle 2a is moved. Swings up and down. In the present embodiment, when the workpiece W swings within a range L1 of 90 degrees up and down 45 degrees with respect to the horizontal position 0 degrees of the grindstone T (FIG. 6), as if the workpiece W is as shown in FIG. 6B. W moves as if W is moving up and down.

The workpiece rotation mechanism 2 having the above-described configuration is mounted on the base 10 so as to be able to swing left and right in a horizontal posture by the swing mechanism S2 disposed on the base 10, and is centered on the central axis 2a on the base 10. Swing left and right. A slide operation mechanism Sa that moves back and forth toward the workpiece W is provided below the turret rotating plate 4 (FIG. 1).
Further, the grindstone rotating mechanism 2 can also perform a sliding operation (sliding operation in a horizontal posture) to the left and right around the central axis 2a on the base 10 so as to correspond to the workpiece rotating mechanism 2. Correspondingly, the other vertical plate 14 is also provided with a mechanism S3 that swings left and right (FIG. 4). That is, the left-right swing mechanism S3 swings left and right around the central axis 2a via the connecting plate S2b, and the turret rotating disk 4 is arranged on the base 10 via the connecting plate S1a. On the base 10, along the arc-shaped groove Rm formed in the plate, the vertical plate 14 is structured to be driven to swing left and right in an arc shape. Note that the rack and pinion mechanisms 6a and 6b described above may be driven.

Four turret rotating disks 4 of the present embodiment are arranged on the outer periphery (presenting a cross in a plane), and are rotated to switch to another grindstone T when one grindstone T is worn. As shown in FIG. 5, the connection release means 7, 6 a, 6 b, 9 a, 9 b includes a grindstone drive means with four rotating shafts 3 at the center of the turret rotating disk 4 by a rotary driver mechanism 6 a 6 b and a miter gear (bevel gear) 9 c. The rotational force of the main shaft 2a of M1 is transmitted to the connecting shaft 7, and this connecting shaft 7 releases the connection with the main shafts (four main shafts) that rotate the plurality of grindstones (FIG. 4). That is, in the center of the turret rotating disk 4, the concave and convex rotary drivers 6a and 6b are arranged, and the concave and convex sides are fitted to each other to form a rotating structure. A miter gear (umbrella) is attached to the rotary drivers 6a and 6b. (Gear) 9c is fitted and rotated. The rotating shaft 9a of the grindstone driving means M1 is fitted and rotated with the miter gear (bevel gear) to rotate the connecting shaft 7. The connection shaft 7 and the main shaft 13 of the plurality of grindstones T are released by releasing the pin insertion. The grindstone T has a ball joint (universal joint) 8 a attached to the tip of each of the plurality of main shafts 3. Therefore, the shaft 9a of one grindstone driving means M1 is alternately switched to the plurality of rotating shafts 3 via the connection release means 7, 6a, 6b, 9a, 9b, 9c. In one direction of rotation, the grindstone T is rotated, but in the opposite direction, the clutch is disengaged and the grindstone T is not rotated. During that time, the rotation driver mechanism 6a6b and the miter gear (bevel gear) 9c cause another grindstone T to rotate. Enter the system to move. The concave rotation drivers 6 a and 6 b are connected to the holding ring 5. Reference numeral 7 denotes a connecting shaft 7 that rotates in connection with the main shaft 3 of the grindstone, and a bearing is disposed on the outer periphery thereof.
As the grindstone T, a so-called cup grindstone T is used (for the work outer side and the inner side, and the taper (inclination) of the right and left corners is different), and the gripping means 8 is provided. Joint operation is performed by the universal joint 8a. Therefore, the contact angle with respect to the workpiece W can be changed via the universal joint 8a.

Further, left and right swing mechanisms S2 for swinging the turret rotating disk 4 are provided. As shown in FIG. 5, the left and right swing mechanism S2 includes a turret rotating worm wheel 15a disposed on the turret rotating plate 4, a turret rotating worm wheel 15a disposed on the turret rotating plate 4, and a turret. The worm gear 15b interlocked with the motor M2 is configured to rotate the turret rotating worm wheel 2a, thereby causing the turret rotating disk 4 to swing in the horizontal direction. The center of the turret rotating worm wheel 15a is disposed on the outer periphery of the rotating shaft 9a of the grindstone driving means M1. The turret motor M2 is mounted on the turret rotating disk 4. The turret rotating disk 4 rotates in the horizontal direction (rotates in one direction) and swings in the direction opposite to the rotation direction (left and right swinging operation). Is also possible. Accordingly, the turret rotating disk 4 is swung with respect to the workpiece W in the left and right directions in the rotation direction and the opposite direction.
Here, it is also possible to arrange the turret rotating disk 4 in a vertical posture. In this case, the rotation for exchanging four turrets and the worm wheel 15a for rotating the turret disposed on the turret rotating disk 4 are used. And a worm wheel 15a for rotating the turret disposed on the turret rotating disk 4 and a worm gear 15b interlocked with the turret motor M2, and the turret rotating worm wheel 2a is rotated in the vertical direction, whereby the turret The turntable 4 can be swung up and down.

Next, the actual example which processes an outer peripheral surface and an inner spherical surface using the honing processing apparatus 1 of the said structure is demonstrated.
First, the turret rotating disk 4 is moved to the position of the work W indicated horizontally by the slide mechanism S.
And when processing the outer periphery of the workpiece | work W, the workpiece | work rotation mechanism 12 rotates the workpiece | work W with the horizontal attitude | position used as the reference | standard (FIG. 9). On the other hand, the grindstone rotating mechanism 2 is swung left and right around the workpiece W by the left and right rocking mechanism S2. That is, when the turret motor (servo motor for driving the turret rotating disk 4) M2 is driven, the shaft rotates the turret rotating disk 4 in the horizontal direction via the worm wheel 15a and the worm gear 15b, that is, the rotation direction in the horizontal direction. And swing in the opposite direction. Note that O is a horizontal line for spindle processing.
When wear of the grindstone T occurs, the turret rotating disk 4 is rotated, and the grindstone T at the tip of each turret (rotating body) 4a is rotated and replaced for use. The rotation direction at this time is the same rotation direction (horizontal rotation) as that of the left-right swing operation S2. Accordingly, since the operation is the same as that of the left and right, even if one grindstone T is worn, the turret rotating disk 4 can be rotated and ground with the new grindstone T. Further, when the turret rotating disk 4 is swung, the workpiece W can be processed as a left and right swinging operation in the horizontal direction.
Further, machining can be performed by adding a swinging operation S1 that swings the workpiece rotating mechanism 12 up and down. As shown in FIGS. 10A and 10B, the workpiece is further swung up and down for processing. If it does in this way, the outer peripheral surface of the workpiece | work W rotatably supported can be ground and changed continuously to an up-down direction.

Here, the work rotating mechanism 12 swings on the circumference L1 around the contact point with the grindstone T, while the grindstone rotating mechanism swings left and right in the horizontal direction by the turret rotating disk 4. Therefore (the point of contact between the workpiece W and the grindstone T is defined as the position of the central axis 2a (the O position in FIG. 8), and the curved surface or spherical surface of the workpiece W is accurately machined by continuous movement. Can do.
Further, machining can be performed by adding a swinging operation S1 that swings the workpiece rotating mechanism 12 up and down. As shown in FIGS. 11A and 11B, the workpiece is further swung left and right for processing. If it does in this way, the outer peripheral surface of the workpiece | work W supported by rotation can be ground by changing continuously in a horizontal direction and an up-down direction.
The turret rotating disk 4 can be equipped with a grindstone T1 for machining the inner circumference side of the workpiece W and a grindstone T2 for machining the outer circumference side. The grindstone T1 for processing the inner peripheral side of the workpiece W and the grindstone T2 for processing the outer peripheral side are different in the R shape of the grindstone at the left and right corners. Accordingly, when machining the inner curved surface (inner circumferential surface) Wa and the outer curved surface (outer circumferential surface) Wb of the workpiece W, the corresponding inner processing grindstone T1 and outer processing grindstone T2 are exchanged and processed. Continuous grinding can be performed efficiently by using any one of the grindstones.

  As described above, in the present embodiment, the grindstones having different roughness may be used. Moreover, although the some grindstone T demonstrated in the example of four pieces, it is possible to reduce or increase more than this.

1 Honing machine,
2 grinding wheel rotation mechanism, 2a central axis,
3 Turret rotation axis (grinding wheel rotation spindle),
4 Turret turntable, 4a Turret (rotary body),
6a, 6b Connection release means (rotary driver),
7 connection shaft (connection release means),
8 Grip mechanism (chuck),
9a Miter gear (connection release means),
12 Work rotation mechanism,
13 Axis for rotating workpiece (rotary axis),
14 Vertical plate,
Sa slide mechanism before and after,
S1 vertical swing mechanism, L1 vertical swing mechanism swing range,
S2 Left and right swing mechanism, L2 Left and right swing mechanism swing range,
S3 Left and right swing mechanism, L3 Left and right swing mechanism swing range,
M1, M2, M3, M4, M5 motor (driving means),
M1 grinding wheel driving means,
M4 vertical drive means (vertical drive means),
T, T1 grinding wheel (grinding wheel for outside processing),
T, T2 grinding wheel (grinding wheel for inner processing),
W work, Wa work outer surface, Wb Work outer surface

Claims (6)

In a honing machine equipped with a workpiece rotation mechanism that rotates a workpiece and a grindstone rotation mechanism that rotates a grindstone, and that processes the curved surface and spherical surface of the workpiece,
The grindstone rotating mechanism connects a turret rotating disk on which a plurality of grindstones are arranged on the outer periphery, one grindstone driving means for rotating each axis of the plurality of grindstones, and a plurality of grindstone rotating shafts and axes of the grindstone driving means. A honing apparatus characterized by comprising a connection release means for releasing, and switching and driving the grindstone rotating shaft via the connection release means. In a honing machine equipped with a workpiece rotation mechanism that rotates a workpiece and a grindstone rotation mechanism that rotates a grindstone, and that processes the curved surface and spherical surface of the workpiece,
The grindstone rotating mechanism includes a turret rotating disk in which a plurality of grindstones are arranged on the outer periphery, and a turret driving unit that rotates the turret rotating disk, and is used by rotating the turret rotating disk to replace a plurality of grindstones. A honing apparatus comprising a left and right swing mechanism for swinging a turret rotating disk in a direction opposite to the rotation direction with respect to a work supported by the work rotation mechanism.   3. The honing according to claim 1, wherein a plurality of grindstones of the turret rotating disk are provided with a grindstone for machining an inner peripheral surface of the workpiece and a grindstone for machining an inner curved surface or an inner spherical surface of the workpiece. Processing equipment.   The honing apparatus according to any one of claims 1 to 3, wherein the work rotation mechanism includes a vertical swing mechanism that swings the work up and down and a left-right swing mechanism that swings the work left and right.   The work rotation mechanism includes a vertical swing mechanism that swings the work up and down, and the grindstone rotation mechanism includes a left-right swing mechanism that swings left and right relative to a horizontally supported work. The honing apparatus according to any one of claims 1 to 3.   When machining the outer curved surface and the inner curved surface of the workpiece, the workpiece horizontally supported by the workpiece rotating mechanism is swung up and down by the vertical rocking mechanism of the grindstone rotating mechanism and / or the left and right rocking mechanism. The honing apparatus according to claim 4, wherein the honing apparatus is rocked to the left and right.