JPH04113003U - Curvature radius measuring device - Google Patents

Abstract

(57) [Summary] [Purpose] Bring the object to be measured, such as a lens, into contact with the reference ring,
When measuring the radius of curvature, uniform contact is made possible and highly accurate measurement is performed. [Structure] The contact terminal 3 is inserted into the center of the reference ring 2, and the amount of linear displacement of the contact terminal 3 is read from the dial gauge 1. For measurement, the lens 6 is brought into contact with the open end of the reference ring 2, and the contact terminal 3 is displaced. A constant pressure device 5 is connected to the reference ring 2 via a tube 4, and the inside of the reference ring 2 is brought into a reduced pressure state when the lens 6 comes into contact with the reference ring 2. Since the lens 6 contacts the reference ring in a reduced pressure state with a uniform force, measurement accuracy is improved.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

This invention relates to a radius of curvature measuring device that measures the radius of curvature of objects to be measured such as lenses. do.

0002

[Conventional technology]

Optical components such as lenses must maintain the curvature of their optical surfaces with high precision, and their manufacturing The optical surface is measured during the manufacturing process. The measurement of optical surfaces such as the spherical surface of this lens is There are different methods for each process such as lining, smoothing, and polishing. It is common to For example, in grinding and smoothing processes, the ball This was done by comparison with the Newton prototype using a ring ferometer, commonly known as a surface meter. In order to improve this measurement accuracy, air micrometers and electric micrometers are being used. etc. are used. In addition, in the smoothing process, Newtonian prototypes and laser Measurements and inspections will also be made using laser interferometers.

0003 Figure 4 shows a conventionally used curvature radius measuring device, which has an open end at the bottom. The dial gauge 41 is provided with a reference ring 42 and a dial gauge 41 located above the reference ring 42. Ru. The dial gauge 41 is equipped with a contact terminal 43 inserted into the center part of the reference ring 42. When the lens to be measured is brought into contact with the open end of the reference ring 42, the contact end The child 43 comes into contact with the lens surface and is displaced in a linear direction, and the amount of this displacement is measured by the dial gauge 4. 1 is displayed. The radius of curvature R of a convex lens can be measured by such a device. When measuring, it can be found by R=((D1/2)2 +h12)/2h1 . In the above equation, D1 is the inner diameter of the reference ring 42 that the lens surface of the convex lens contacts. , h1 is the amount of displacement of the contact terminal 43 from the open end of the reference ring 42. measurement pair When the lens is a concave lens, the lens surface abuts the outside of the reference ring 42, so the reference ring Substituting the outer diameter D2 of the contact terminal 42 into the above equation, and changing the contact terminal 43 due to the concave lens. It can be measured by substituting the quantity h2 into the above equation. Such a curvature half When measuring at the production site using a diameter measuring device, prepare a reference spherical surface and use this reference spherical surface. Workers are required to perform relative measurements with the spherical surface at each step.

0004

[Problem that the idea aims to solve]

However, with conventional equipment, the work of bringing the object to be measured, such as a lens, into contact with the reference ring is difficult. Since this is done by the operator, it is not possible to keep the pressure constant during pressing, which can lead to measurement errors. The difference is large and it is difficult to make accurate measurements. Also, place the entire surface of the object to be measured on the reference ring. If it is difficult to contact the edges evenly and the pressing force becomes uneven, There were scratches and other scratches on the measurement surface that had been partially pressed against it. Furthermore, the object to be measured and If there is a foreign object in the contact area with the reference ring, perform accurate curvature measurement. I had a problem where I couldn't do it.

[0005] The present invention was developed in view of the above circumstances, and is designed to uniformly apply the object to be measured to the reference ring. A curvature radius measuring device that can be brought into contact with the user and can be used to accurately measure the radius of curvature. The purpose is to provide

[0006]

[Means to solve the problem]

The radius of curvature measuring device of the present invention has a base having an open end on which the measuring surface of the object to be measured comes into contact. a quasi-ring, and is inserted into the reference ring so as to be located at the center of this reference ring and reaches the open end. It has a contact terminal that is displaced in a linear direction when it comes into contact with an object to be measured, and the amount of displacement of the contact terminal is A scale for detecting The invention is characterized in that it includes a suction means for causing

[0007]

[Effect]

In the above configuration, the inside of the reference ring is depressurized by the suction means, and the measurement target is placed in this depressurized state. Bring the object into contact with the reference ring. This maintains a constant pressure inside the reference ring, so The object to be measured comes into uniform contact with the reference environment, allowing for highly accurate measurements. Also, the criteria If there is a foreign object in the contact area between the ring and the object to be measured, the specified reduced pressure will not be reached. Therefore, by monitoring this reduced pressure value, it is possible to detect the presence or absence of foreign objects. Wear.

[0008]

[Example 1] FIG. 1 shows a first embodiment of the present invention, in which a reference ring 2 is brought into contact with a lens 6 as an object to be measured. and a dial gauge 1 as a scale. Dial gauge 1 is the base It has a contact terminal 3 inserted into the central part of the semi-ring 2. Reference ring 2 is open at the bottom When the lens 6 comes into contact with this open end, the contact terminal 3 moves in a straight direction. The dial gauge 1 displays the amount of displacement. This allows the curvature of the lens surface to Radius measurements can be made. In addition to the above configuration, this embodiment also includes a suction means. It is provided. The suction means was connected to the upper part of the reference ring 2 by a connector 16. A tube 4 and a low pressure device 5 connected to the tube 4 via a connector 17. It is composed of. The low pressure device 5 reduces the pressure inside the reference ring 2 by vacuum suction. At the same time, it operates to maintain the negative pressure value within the reference ring 2 due to the reduced pressure.

[0009] In such a configuration, air within the reference ring 2 is supplied to the pneumatic device 5 via the tube 4. , so that by simply bringing the lens 6 close to the opening end of the reference ring 2, the lens 6 is sucked by the negative pressure inside the reference ring 2 and pressed against the open end surface of the reference ring 2. come into contact with

0010 This contact is made with a constant pressure due to the negative pressure inside the reference ring 2, so the lens 6 Positioning is always performed with a predetermined suction force. For this reason, there is a difference in the pressing force applied by the worker. This eliminates the variation in measured values caused by this, allowing highly accurate measurements to be made. Also , because the lens 6 does not come into strong partial contact with the reference ring 2 due to an operational error. , the lens 6 will not be scratched or chipped. Furthermore, the reference ring 2 and the lens 6 If a foreign object is present at the contact site, this can be detected. Sunawa If foreign matter is present, the specified negative pressure will not be reached, so the constant pressure device 5 is used to monitor the negative pressure. The presence or absence of foreign matter can be detected by monitoring. And after this foreign body detection , by removing and measuring, accurate measurements can be made.

[0011]

[Example 2] FIG. 2 shows a second embodiment of the present invention, in which the same elements as in the first embodiment are denoted by the same reference numerals. It is shown. In this embodiment 2, the reference ring 2 whose open end faces upward and the center of the reference ring 2 A spherical meter 20 is constituted by the contact terminal 3 inserted into the spherical meter. 20 is held at the tip of the arm 7. The base end of arm 7 is indexed. It rotates while being connected to the rotating shaft of the shaft 18. The rotation area of arm 7 includes a master rail. An adapter shaft 9 holding a lens 8 and a lens holding a lens 6 to be measured. A holder 10 is provided. The lens holder 10 is attached to the lower end of the work shaft 12. It is attached and connected to a decompression device (not shown), and holds the lens 6 by suction. . Furthermore, a grindstone 1 for grinding and polishing the lens 6 is provided below the lens holder 10. 3 is attached to the lower shaft 14. In addition, master lens 8 The adapter shaft 9 that holds the lens 6 and the work shaft 12 that holds the lens 6 are It can be moved up and down by a holder (not shown). In addition, the position close to the lens 6 A nozzle 15 for spraying air onto the lens 6 is provided at the lens 6. In addition, The contact terminal 3 is connected to a curvature measuring device 11 via a cord. This curvature measuring device 1 1 detects the amount of displacement of the contact terminal 3 and calculates the half of the curvature of the lens 6 from the amount of displacement. It is configured to measure the diameter and display it digitally.

0012 Next, the operation of the above configuration will be explained.

[0013] Lens b is transferred from the curve generator process to the lens holder by a conveying means (not shown). The lens is transported to the lens holder 10 and held by suction on the lens holder 10 by the operation of the decompression device. be done. Next, the arm 7 is rotated by the drive of the motor and the lower part of the master lens 8 is rotated. Move to measurement position. At this time, the master lens 8 is held on the adapter shaft 9. It is placed in a fixed position. Arm 7 reaches the measurement position below master lens 8 Then, the adapter shaft 9 is lowered by the cylinder, and the master lens 8 is moved to the arm. 7. Contact the spherical meter 20 held at the tip while reducing the speed to measure the curvature. The radius of curvature is measured by the measuring device 11. When this measurement is completed, the adapter shaft 9 It is raised by the cylinder and returns to its original position before descending. Then index 1 The arm 7 attached to the rotating shaft of the spherical meter 2 is rotated by the drive of the motor. 0 is located directly below the work shaft 12. This allows the work shaft 12 to control the speed. A device that can roll (not shown) lowers the speed while descending. The lenses 6 come into contact with the spherical meter 20. Then, the decompression device stops and the lens holder 1 The suction holding of the lens 6 by 0 is released, and the lens 6 is placed on the spherical meter 20 by its own weight. Ru. At this time, the air inside the reference ring 2 is sucked by the pneumatic device 5, and the lens 6 is moved into the reference ring. 2, and the radius of curvature is measured using the curvature measuring device 11. This Len The curvature is the difference between the measured value of the curvature of lens 6 and the measured value of master lens 8, which was measured earlier. Measurement is performed automatically using the measuring device 11.

[0014] After completing the measurement of the curve generator machined surface as described above, the pneumatic device 5 is The suction of air inside the reference ring 2 is released, and the lens 6 is attracted to the lens holder 10. The work shaft 12 rises and returns to its regular position, and the arm 7 is moved by the motor. -Returns to normal position by driving. After that, the work shaft 12 is lowered and the lens 6 is polished. The lens contacts the stone 13 and is rotated by the rotation mechanism and swing mechanism (not shown) of the lower shaft 14. Perform the grinding/polishing process in step 6. After machining for a predetermined time, the work shaft 12 is raised and positioned After returning to the position, air is blown onto the lens 6 from the nozzle 15, cleaning the lens 6. Purify. During the above grinding and polishing process, the adapter shaft 9 is lowered by the drive of the cylinder. Then, the master lens 8 is sent to the spherical meter 20 held at the tip of the arm 7. The curvature radius is measured by the curvature measuring device 11. child When the measurement is completed, the adapter shaft 9 rises and returns to the normal position, and the arm 7 moves to the measurement position of the lens 6 which has finished grinding and polishing. This results in Measure the radius of curvature using the same procedure as measuring the radius of curvature of the curve generator machined surface. conduct.

[0015] According to this embodiment, the lens 6 is moved by the suction force of the pneumatic device 5 when measuring the radius of curvature. Since it is pressed against the open end face of reference ring 2 with a constant pressure, the curvature can be measured automatically. This can be done with high precision. Therefore, the amount of time required to measure lens curvature is The number of personnel and man-hours required can be significantly reduced. Furthermore, in addition to the above configuration, the curvature The spherical meter 20 connected to the measuring device 11 is connected to a curve generator processing machine and a lens processing machine. By connecting to the line controller that controls the entire equipment that performs the work, Automatic measurement of lens curvature radius after blade generator processing and after grinding/polishing processing and automatic correction can be performed.

[0016]

[Example 3] FIG. 3 shows a third embodiment of the present invention, in which the same elements as in the second embodiment are denoted by the same reference numerals. I have responded. In this third embodiment, the spherical meter 20 is located at the lower end of the cylinder 21 in the vertical direction. At the same time, this cylinder 21 is attached to a mounting base 22, and this cylinder 21 is attached to a mounting base 22. A mounting base 22 is attached to a horizontal cylinder 23. This allows the spherical meter to 20 is movable up and down and back and forth. In addition, the base that supports these A rotary cylinder 25 is attached to the stand 27, and a rotary cylinder 25 is attached to the stand 27. A conveyor belt 26 is located nearby. The rotary cylinder 25 has a rotating An arm 28 is attached to the rotary arm 28, and the lens is removed by reducing pressure. A suction piece 24 for suctioning 6 is attached. In addition, the contact terminal 3 of the spherical meter 20 is connected to the curvature measuring device 11, and the radius of curvature is measured based on the amount of displacement. , the reference boundary 2 is connected to a constant pressure device 5 via a tube 4.

[0017] In this configuration, when the lens 6 is conveyed by the conveyor belt 26, the The rotary arm 28 rotates 90 degrees due to the operation of the tally cylinder 25, and the suction piece 2 4 comes into contact with the lens 6. As a result, the lens 6 is suctioned and held by the suction piece 24, and After that, the rotary arm 28 is rotated 180° by the rotary cylinder 25, and the lens is rotated by 180 degrees. Move the lens 6 to the measurement position directly below the spherical meter 20. Lens 6 is directly below the spherical meter 20 When the measurement position is reached, the spherical meter 20 is brought into contact with the lens 6 by the operation of the cylinder 21. come into contact with At this time, the suction holding of the suction piece 24 is released by stopping the air suction. Then, the air inside the reference ring 2 is sucked by the pneumatic device 5, and the lens 6 is inserted into the opening of the reference ring 2. Adsorb it to the end surface.

[0018] Thereby, the radius of curvature of the lens 6 is measured by the curvature measuring device 11. Measurement is finished. Once completed, the spherical meter 20 is moved by the cylinder 21 with the lens 6 still adsorbed. Rise to a preset height. Then, the cylinder 23 operates and the lens The mounting base 22 is moved horizontally so that the conveyor belt 6 is positioned directly above the conveyor belt 26. So Then, the spherical meter 20 is lowered by the operation of the cylinder 21, and the lens 6 is placed on the conveyor belt. contact with the root 26. At this time, the lens 6, which is suctioned and held by the reference ring 2, is held under constant pressure. It is released by stopping the air suction of the device 5, and the lens 6 is transferred onto the conveyor. When this operation is completed, the spherical meter 20 rises due to the operation of the cylinder 21, and then The cylinder 23 moves horizontally and returns to the original position, and the rotating arm The cylinder 28 also rotates 90 degrees and returns to its original position due to the operation of the rotary cylinder 25. do.

[0019] According to this embodiment, the lens 6 is referenced by the suction force of the pneumatic device 5 when measuring the curvature. The radius of curvature can be measured with high precision and variation because it comes into contact with the open end surface of ring 2 with a constant pressure. In addition to being able to perform measurements automatically within the lens reversing device, This greatly reduces the number of people and man-hours required to measure the radius of curvature of a lens. . Furthermore, in this embodiment, the master lens 8 is placed directly below the spherical meter 20, and the lens Before the lens 6 is conveyed by the rotary arm 28, the spherical meter 20 is placed in the cylinder 21. Lower the lens further, bring it into contact with the master lens 8, and measure the master lens using the curvature measuring device 11. The curvature of the lens 8 can be measured. As a result, the ratio with master lens 8 Since it is possible to perform comparative measurements, it is possible to measure the radius of curvature with higher accuracy.

[0020]

[Effect of the idea]

In this invention, when measuring the radius of curvature by bringing the object to be measured into contact with the open end of the reference ring, The suction means reduces the pressure inside the reference ring to ensure uniform contact, ensuring reliable and accurate contact. It is possible to make precise contact with the object to be measured, and to perform highly accurate measurements. It won't hurt you. It also detects the presence or absence of foreign objects at the contact point between the reference ring and the measured object. It is also possible to prevent a decrease in measurement accuracy due to the presence of foreign matter.

[Submission date] July 4, 1991

[Procedural amendment 1]

[Name of document to be amended] Specification

[Correction target item name] 0003

[Correction method] Change

[Correction details]

FIG. 4 shows a conventionally used curvature radius measuring device, which includes a reference ring 42 having an open end at the bottom and a dial gauge 41 located above the reference ring 42. The dial gauge 41 is equipped with a contact terminal 43 that is inserted into the center of the reference ring 42. When the lens to be measured is brought into contact with the open end of the reference ring 42, the contact terminal 43 is brought into contact with the lens surface. It is displaced in a linear direction, and the dial gauge 41 displays the amount of displacement. When measuring the radius of curvature R of a convex lens using such a device, it can be determined by R=((D ₁ /2) ² +h ₁ ² )/2h ₁ . In the above equation, D ₁ is the inner diameter of the reference ring 42 that the lens surface of the convex lens contacts, and h ₁ is the amount of displacement of the contact terminal 43 from the open end of the reference ring 42 . When the object to be measured is a concave lens, the lens surface comes into contact with the outside of the reference ring 42, so the outer diameter D ₂ of the reference ring 42 is substituted into the above equation, and the displacement h ₂ of the contact terminal 43 due to the concave lens is It can be measured by substituting it into the equation. For measurements at production sites using such a curvature radius measuring device, a reference spherical surface is prepared, and a worker performs relative measurements with this reference spherical surface for each process.

[Brief explanation of drawings]

FIG. 1 is a front view of Embodiment 1 of the present invention.

FIG. 2 is a sectional view of Embodiment 2 of the present invention.

FIG. 3 is a perspective view of Embodiment 3 of the present invention.

FIG. 4 is a front view of a conventional device.

[Explanation of symbols]

1 Dial gauge 2 Reference ring 3 Contact terminal 4 tube 5 Constant pressure device 6 Lens

Claims (1)

[Scope of utility model registration request] 1. A reference ring having an open end with which the measurement surface of the object to be measured comes into contact, and a reference ring that is inserted into the reference ring so as to be located at the center of the reference ring so that the object to be measured comes into contact with the open end. The measuring device has a contact terminal that is tangentially displaced in a linear direction, a scale that detects the amount of displacement of the contact terminal, and a suction means that reduces the pressure in the reference ring and brings the object to be measured into contact with the reference ring. A curvature radius measuring device characterized by: