The present invention relates to a method for manufacturing a component, such as a spherical lens, particularly used in optical devices, and also relates to a polishing apparatus.
A spherical lens, which is an optical element used in optical devices, is polished by supplying abrasive slurry to a polishing tool having a spherical operating surface similar to the surface of the spherical lens, causing the polishing tool to apply pressure to a workpiece, and also causing the polishing tool to rotate the workpiece and make the workpiece perform an oscillating movement. The oscillating movement is performed, with the center of curvature of the surface of the workpiece coinciding with the center of curvature of the surface of the polishing tool. This oscillating movement transfers the surface shape of the polishing tool to the optical element, so that a desired shape of the optical element can be obtained.
As a polishing apparatus that polishes a spherical lens, Japanese Patent Publication No. 6-65460 describes a polishing apparatus that performs polishing by applying pressure toward the spherical center of a polishing plate to make the polishing plate oscillate. Japanese Patent No. 4347374 describes a polishing apparatus that includes linear motion shafts provided with linear guides. By controlling each of the linear motion shafts, this polishing apparatus performs an oscillating movement in which the center of curvature of the surface of the workpiece coincides with the center of curvature of the surface of the polishing tool.
Each of the polishing apparatuses described in Japanese Patent Publication No. 6-65460 and Japanese Patent No. 4347374 is configured to make the polishing plate oscillate and is distant from the spherical center. Therefore, since the range of oscillation is large, it is necessary to improve apparatus stiffness and movement accuracy to achieve a high-accuracy oscillating movement, and this increases the apparatus cost. Lowering the cost of the polishing apparatus leads to an increase in spherical center error due to a decrease in apparatus stiffness and movement accuracy. This causes a nonuniform distribution of contact pressure between the surface of the workpiece and the surface of the polishing tool, and makes it difficult to achieve desired shape accuracy.
A component manufacturing method according to an aspect of the present invention is a method for manufacturing a component by moving a workpiece with respect to a polishing tool to polish the workpiece, and includes causing a holding member to hold the workpiece such that a spherical center of a processed surface of the workpiece is located on a supporting member; rotating the workpiece by rotating the holding member; and polishing the workpiece by moving the supporting member to move the workpiece on the polishing tool, with the spherical center of the processed surface located at a spherical center of a processing surface of the polishing tool.
A polishing apparatus according to another aspect of the present invention is an apparatus that polishes a workpiece by moving the workpiece with respect to a polishing tool, and includes a holding member configured to hold the workpiece; a work rotating mechanism configured to rotate the holding member; a supporting member configured to come into contact with the holding member; and a moving mechanism configured to move the supporting member. A rotation transmitting member is coupled to the holding member, and the rotation transmitting member transmits rotation from the work rotating mechanism to the holding member.
A component manufacturing method according to another aspect of the present invention is a method for manufacturing a component by moving a workpiece with respect to a polishing tool to polish the workpiece, and includes holding the workpiece such that a spherical center of a processed surface of the workpiece is located on a supporting member; attaching the supporting member to an articulated arm formed by a plurality of arms coupled together by a plurality of joints, with the spherical center of the processed surface located at a spherical center of a processing surface of the polishing tool; and polishing the workpiece by driving the joints to move the supporting member such that the workpiece moves on the polishing tool.
A polishing apparatus according to another aspect of the present invention is an apparatus that polishes a workpiece by moving the workpiece with respect to a polishing tool, and includes a holding member configured to hold the workpiece; a supporting member configured to come into contact with the holding member; and an articulated arm configured to move the supporting member, the articulated arm being formed by a plurality of arms coupled together by a plurality of joints. The supporting member is moved by driving each of the plurality of joints of the articulated arm.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
A first embodiment of a component manufacturing method according to the present invention will now be described.
Referring to
The workpiece holding unit B includes a supporting member 6 and a holding member 7 for holding a workpiece 9. The holding member 7 holds the workpiece 9 such that an optical axis passing through a spherical center O of a processed surface 9a of the workpiece 9 is located on a central axis of the holding member 7. A spherical center of the workpiece 9 may be either a spherical center of the workpiece 9 before polishing or a spherical center of a shape to be obtained by polishing (i.e., target shape), but the latter is more preferable.
As illustrated in
Using an elastic member as the rotation transmitting member 62 can reduce a moment stiffness around any axis intersecting the rotation axis of the workpiece 9. Therefore, even if a spherical center error of the polishing apparatus is relatively large, that does not block the force of enabling the workpiece 9 to follow the movement of the polishing tool 8. Thus, a pressure from the polishing tool 8 is uniformly applied to the surface of the workpiece 9, and good shape accuracy can be achieved. Since the rotation speed of the workpiece 9 is mechanically controlled by the rotation transmitting member 62, a moving speed (polishing speed) of the surface of the workpiece 9 relative to the surface of the polishing tool 8 can be controlled, and better shape accuracy can be achieved. Since the polishing speed can be set properly in accordance with the material and the target shape accuracy, the processing time can be shortened. Also, wear of the surface of the polishing tool 8 or wear of a coupling portion between the holding member 7 and the supporting member 6 does not cause the moving speed (polishing speed) of the surface of the workpiece 9 relative to the surface of the polishing tool 8 to change with time. Therefore, it is possible to stabilize the speed of removing the surface of the workpiece 9, and ensure good shape accuracy of a processed component.
The polishing tool 8 may be rotated by the tool rotating mechanism (not shown). To make the speed of the surface of the workpiece 9 relative to the surface of the polishing tool 8 constant, the rotation speed of the workpiece 9 may be made equal to that of the polishing tool 8.
A pressure mechanism may be provided, which applies pressure by moving the supporting member 6 in a direction parallel to the central axis T to press the workpiece 9 against the polishing tool 8.
The moving mechanism unit C is configured to move the supporting member 6. With the spherical center of the processed surface 9a located at the spherical center of the processing surface 8a of the polishing tool 8, the moving mechanism unit C moves the supporting member 6 such that the workpiece 9 moves on the polishing tool 8.
Specifically, moving the supporting member 6 involves:
(1) positioning the supporting member 6 of the workpiece holding unit B such that the spherical center of the processed surface 9a of the workpiece 9 is located at the spherical center O of the processing surface 8a of the polishing tool 8; and
(2) making the supporting member 6 serve as an oscillating shaft to move the workpiece 9 (or to cause the workpiece 9 to perform an oscillating movement) on the polishing tool 8, with the spherical center O of the processed surface 9a of the workpiece 9 and the processing surface 8a of the polishing tool 8 being a center of the oscillation (e.g., making the workpiece 9 reciprocate in the radial (R) direction of the polishing tool 8 (oscillation direction).
In the first embodiment, an articulated arm is used as the moving mechanism unit C. That is, the supporting member 6 is attached to the articulated arm. The articulated arm is formed by a plurality of arms coupled together by a plurality of joints. The articulated arm moves the supporting member 6 by driving each joint. In
However, it is inevitable that the oscillating movement will cause a small spherical center error. The spherical center error refers to a distance between the center of curvature of the surface of the workpiece 9 and a center of curvature of the surface of the polishing tool 8 during oscillating movement. The spherical center error may cause a nonuniform distribution of contact pressure between the surface of the workpiece 9 and the surface of the polishing tool 8 (i.e., uneven contact where pressure is concentrated in a particular area), and may make it difficult to achieve desired shape accuracy. The uneven contact caused by the spherical center error is prevented by allowing inclination of the coupling part 16 between the holding member 7 and the supporting member 6. Thus, even if the spherical center error is large, it is possible to reduce variation in pressure applied from the polishing tool 8 to the workpiece 9 and achieve desired shape accuracy.
A coupling portion between the holding member 7 and the supporting member 6 will now be described in detail.
Referring to
To reduce slippage between the workpiece 9 and the elastic sheet 10, the elastic sheet 10 having a large surface friction coefficient may be used. Also to reduce slippage between the workpiece 9 and the elastic sheet 10, the workpiece 9 may be vacuum-attracted to the holding member 7. The coupling part 16 of the supporting member 6 may be either an integral part of the supporting member 6 or a separate part. The coupling part 16 has the concave spherical portion 161 at an extremity thereof. The concave spherical portion 161 is formed by a concave spherical surface.
The coupling part 16 may be provided with an exhaust flow path 162 that allows the workpiece 9 to be vacuum-attracted to the holding member 7.
The holding member 7 is coupled through the coupling part 16 to the supporting member 6. The holding member 7 has a protrusion 17 at the center thereof. A sliding member 14 is disposed around the protrusion 17. The sliding member 14 comes into contact with the concave spherical portion 161 of the coupling part 16, so that the holding member 7 is connected to the supporting member 6. The sliding member 14 may be made, for example, of synthetic resin or rubber.
The holding member 7 may be provided with an exhaust flow path 172 that allows the workpiece 9 to be vacuum-attracted to the holding member 7. An outer cylinder 11 is attached to the outer periphery of the holding member 7. Since the workpiece 9 is placed inside the outer cylinder 11, the workpiece 9 can be supported at a proper position of the holding member 7 without sticking out of the holding member 7. Also, the workpiece 9 can be restrained in the oscillation direction (R direction).
As described above, by controlling the arm joint 1, the arm joint 3, and the arm joint 5 illustrated in
The sliding member 14 is a mechanism that slides on the spherical surface of the concave spherical portion 161 of the coupling part 16. The central axis of the holding member 7 (workpiece 9) can be inclined with respect to the central axis of the supporting member 6, with the center of curvature P1 of the concave spherical portion 161 of the coupling part 16 being a supporting point. The holding member 7 is rotatable with respect to the supporting member 6. Therefore, if a spherical center error occurs during oscillating movement, the central axis of the holding member 7 is freely inclined from the central axis T of the supporting member 6. Since the holding member 7 is rotatable with respect to the supporting member 6, it is possible to allow the workpiece 9 to follow the movement of the processing surface 8a of the polishing tool 8 without causing a nonuniform distribution of pressure over the surface of the workpiece 9. It is thus possible to reduce a spherical center error (i.e., variation in distance between the center of curvature of the surface of the workpiece 9 and the center of curvature of the surface of the polishing tool 8 during oscillating movement).
An angle θ between the optical axis (central axis) of the workpiece 9 and a line segment QP1 connecting the center of curvature P1 of the concave spherical portion 161 of the coupling part 16 to a contact point Q between the sliding member 14 and the coupling part 16 may satisfy the following expression (1):
tan θ≥μ (1)
where μ is a coefficient of kinetic friction between the workpiece 9 and the polishing tool 8 during polishing. Expression (1) can be expressed by expression (2) below:
where d is a diameter of the sliding member 14 and r is a curvature radius of the concave spherical portion 161 of the coupling part 16.
After the value of θ, R, or d satisfying expression (1) or (2) is determined, the holding member 7, the coupling part 16, and the sliding member 14 are made. It is thus possible to achieve stable polishing without causing the sliding member 14 to fall off the concave spherical portion 161 of the coupling part 16 by frictional force produced between the workpiece 9 and the polishing tool 8 during polishing.
With this configuration, the central axis of the holding member 7 (i.e., the optical axis or central axis of the workpiece 9) is made coaxial with the central axis T of the supporting member 6 when there is no spherical center error. Even if a spherical center error occurs, since the central axis of the holding member 7 can be inclined with respect to the central axis T of the supporting member 6 and the holding member 7 is rotatable with respect to the supporting member 6, the workpiece 9 can be processed with little occurrence of uneven contact, and desired shape accuracy can be achieved. The term “uneven contact” means that a force from the polishing tool 8 is not uniformly applied to the workpiece 9 during processing and is concentrated in a particular area of the workpiece 9.
A distance D1 between the center of curvature P1 of the concave spherical portion 161 of the coupling part 16 and the center of the processed surface 9a of the workpiece 9 may be small. A large distance D1 causes a nonuniform distribution of frictional force between the workpiece 9 and the polishing tool 8 during polishing. This increases the moment of the holding member 7 produced about the center of curvature P1 of the concave spherical portion 161 of the coupling part 16, causes uneven contact in the workpiece 9, and makes it difficult to process the workpiece 9 with high accuracy. With the configuration of the first embodiment, however, the distance D1 between the center of curvature P1 of the concave spherical portion 161 of the coupling part 16 and the center of the workpiece 9 can be reduced. Therefore, the workpiece 9 can be processed with high accuracy even when it has a large thickness at the center thereof.
A second embodiment of the present invention will now be described. The holding member 7 and the coupling part 16 which are different from those in the first embodiment will be described.
The holding member 7 has a concave portion 19 at the center thereof, and the coupling part 16 has a convex spherical portion 163 at an extremity thereof. The concave portion 19 of the holding member 7 is supported by the convex spherical portion 163 of the coupling part 16. The concave portion 19 of the holding member 7 and the convex spherical portion 163 of the coupling part 16 can be inclined. The workpiece 9 is pivotable about a center of curvature P2 of the convex spherical portion 163 of the coupling part 16. Therefore, even if a spherical center error occurs during oscillating movement, the workpiece 9 can follow the movement of the polishing tool 8 without causing a nonuniform distribution of pressure over the surface of the workpiece 9.
As illustrated in
As illustrated in
A distance D2 between the center of curvature P2 of the convex spherical portion 163 of the coupling part 16 and the center of the surface of the workpiece 9 may be small. The distance D between the center of curvature P of the spherical portion of the coupling part 16 and the center of the surface of the workpiece 9 is smaller in the case of the concave spherical portion 161 (first embodiment) than that in the case of the convex spherical portion 163 (second embodiment). Therefore, particularly when the workpiece 9 has a large thickness, the coupling part 16 having the concave spherical portion 161 (first embodiment) may be used.
A third embodiment of the present invention will now be described. The third embodiment relates to conveyance of the workpiece 9.
Referring to
During polishing, as illustrated in
With the polishing method described above, desired shape accuracy of the workpiece 9 can be achieved during polishing even if a spherical center error is large. Also, the position of the holding member 7 for holding the workpiece 9 (component) is stabilized during automatic conveyance, and the workpiece 9 (component) can be conveyed in a stable manner.
The first member 20 or the second member 21 is provided with a mechanism (e.g., a known technique of providing a groove) that transmits rotation of the second member 21 to the first member 20 when the first member 20 and the second member 21 are in a non-contact state. Then by applying rotation from the work rotating mechanism 61 to the second member 21, the holding member 7 can be rotated, so that the workpiece 9 can be processed while being rotated.
In Example 1, an optical member was processed using the first embodiment. A piece of general optical glass having an outside diameter ϕ of 25 mm, a convex shape with a curvature radius R of 28 mm, and a central thickness of 2 mm was used as the optical member.
Polishing was carried out by controlling the arm joint 1, the arm joint 3, and the arm joint 5 illustrated in
In the workpiece holding unit illustrated in
In Example 2, an optical member was processed using the second embodiment. A piece of general optical glass having an outside diameter ϕ of 18 mm, a concave shape with a curvature radius R of 16 mm, and a central thickness of 1 mm was used as the optical member.
Like Example 1, polishing was carried out by controlling the arm joint 1, the arm joint 3, and the arm joint 5 illustrated in
In the workpiece holding unit illustrated in
In Example 3, the same processing as that in Example 2 was carried out and automatic conveyance described in the third embodiment was performed. As illustrated in
Next, the workpiece 9 held by the holding member 7 in
A fourth embodiment of a component manufacturing method according to the present invention will be described. The fourth embodiment does not include the rotation transmitting member 62 of the first embodiment. The same configuration as that of the first embodiment will not be described here.
Referring to
The workpiece holding unit B includes the holding member 7 for holding the workpiece 9 and the supporting member 6. The holding member 7 holds the workpiece 9 such that the optical axis passing through the spherical center O of the processed surface 9a of the workpiece 9 is located on the central axis of the holding member 7. The spherical center of the workpiece 9 may be either a spherical center of the workpiece 9 before polishing or a spherical center of a shape to be obtained by polishing (i.e., target shape), but the latter is more preferable.
The moving mechanism unit C is configured to move the supporting member 6. With the spherical center of the processed surface 9a located at the spherical center of the processing surface 8a of the polishing tool 8, the moving mechanism unit C moves the supporting member 6 such that the workpiece 9 moves on the polishing tool 8.
Specifically, moving the supporting member 6 involves:
(1) positioning the supporting member 6 of the workpiece holding unit B such that the spherical center of the processed surface 9a of the workpiece 9 is located at the spherical center O of the processing surface 8a of the polishing tool 8; and
(2) making the supporting member 6 serve as an oscillating shaft to move the workpiece 9 (or to cause the workpiece 9 to perform an oscillating movement) on the polishing tool 8, with the spherical center O of the processed surface 9a of the workpiece 9 and the processing surface 8a of the polishing tool 8 being a center of the oscillation (e.g., making the workpiece 9 reciprocate in the radial (R) direction of the polishing tool 8 (oscillation direction).
Moving the supporting member 6 involves using an articulated arm as the moving mechanism unit C. That is, the supporting member 6 is attached to the articulated arm. The articulated arm is formed by a plurality of arms coupled together by a plurality of joints. The articulated arm moves the supporting member 6 by driving each joint. In
However, it is inevitable that the oscillating movement will cause a small spherical center error. The spherical center error refers to a distance between the center of curvature of the surface of the workpiece 9 and the center of curvature of the surface of the polishing tool 8 during oscillating movement. The spherical center error may cause a nonuniform distribution of contact pressure between the surface of the workpiece 9 and the surface of the polishing tool 8 (i.e., uneven contact where pressure is concentrated in a particular area), and may make it difficult to achieve desired shape accuracy. The uneven contact caused by the spherical center error is prevented by allowing inclination of the coupling part 16 between the holding member 7 and the supporting member 6. The coupling part 16 between the holding member 7 and the supporting member 6 will not be described here, as it is the same as that in the first embodiment. Thus, even if the spherical center error is large, it is possible to reduce variation in pressure applied from the polishing tool 8 to the workpiece 9 and achieve desired shape accuracy.
The present invention enables the workpiece 9 and the polishing tool 8 to relatively move with high accuracy. It is thus possible not only to process the workpiece 9 with high accuracy, but also to narrow the range of oscillation and lower the cost of the apparatus. It is also possible to control the speed of relative movement of the workpiece 9 and the polishing tool 8 and to shorten the processing time.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
Number | Date | Country | Kind |
---|---|---|---|
2013-151650 | Jul 2013 | JP | national |
2013-151651 | Jul 2013 | JP | national |
This application is a Continuation of U.S. patent application Ser. No. 14/332,789, filed Jul. 16, 2014, which claims the benefit of Japanese Patent Application No. 2013-151650, filed Jul. 22, 2013, and Japanese Patent Application No. 2013-151651, filed Jul. 22, 2013, all of which are hereby incorporated by reference herein in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
2105175 | Anderson | Jan 1938 | A |
2129522 | Burroughs | Sep 1938 | A |
3330075 | Suddarth | Jul 1967 | A |
3886696 | Bruck | Jun 1975 | A |
3900972 | Rupp | Aug 1975 | A |
3916574 | Prunier | Nov 1975 | A |
4173848 | Ikeno | Nov 1979 | A |
4216626 | Starp | Aug 1980 | A |
4598502 | Lombard | Jul 1986 | A |
4653234 | Lombard | Mar 1987 | A |
5241792 | Naka | Sep 1993 | A |
5291692 | Takahashi | Mar 1994 | A |
5482495 | Mayahara | Jan 1996 | A |
5951375 | Mandler | Sep 1999 | A |
6077148 | Klein | Jun 2000 | A |
6123610 | Larsen | Sep 2000 | A |
6247999 | Tokiwa | Jun 2001 | B1 |
6855042 | Werner | Feb 2005 | B1 |
7338346 | Kuebler | Mar 2008 | B2 |
7455569 | Schafer | Nov 2008 | B2 |
20020061717 | Goulet | May 2002 | A1 |
20030129925 | Toyoshima | Jul 2003 | A1 |
20040229553 | Bechtold | Nov 2004 | A1 |
20050101226 | Ferme | May 2005 | A1 |
20060009126 | Kuebler | Jan 2006 | A1 |
20070021036 | Kuebler | Jan 2007 | A1 |
20070293128 | Schafer | Dec 2007 | A1 |
20080305723 | Philipps | Dec 2008 | A1 |
20100151773 | Leonhardt | Jun 2010 | A1 |
20120045975 | Kojima | Feb 2012 | A1 |
20140235142 | Monnoyeur | Aug 2014 | A1 |
20140248824 | Satake | Sep 2014 | A1 |
20150024663 | Torikai | Jan 2015 | A1 |
Number | Date | Country |
---|---|---|
2728915 | May 1979 | DE |
0567894 | Nov 1993 | EP |
1266111 | Mar 1972 | GB |
S53-018088 | Feb 1978 | JP |
2008-260091 | Oct 2008 | JP |
WO 2011092748 | Aug 2011 | JP |
Number | Date | Country | |
---|---|---|---|
20180333822 A1 | Nov 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 14332789 | Jul 2014 | US |
Child | 16048968 | US |