RU172779U1 - Lens Centering Chuck - Google Patents

Abstract

The invention relates to the field of optical instrumentation, in particular to devices for assembling optical components, as well as for assembling and centering lenses in frames. The essence of the technical solution lies in the fact that in the lens centering cartridge containing a housing with a shear part for moving in two mutually perpendicular directions and a rotary part connected with the shear part, the rotary part is made in the form of a spherical washer, the shear part in the form of a face plate, at the same time, central coaxially oriented through holes are made in the housing, the spherical washer and the face plate, and the body itself is placed between the spherical washer and the face plate, which are interconnected by the springs stretching, the pressing washer to the middle portion of the housing in the direction of the common axis of said openings. On the spherical washer and faceplate, mounting threads are made to fix the cartridge on the machine on either side and install the adapters of the centered lenses. The technical result consists in expanding the functionality of the centering cartridge by providing an increase in the range of radii of the centering lenses and working on both surfaces of the lenses, including material that is opaque in visible light, and increasing the centering accuracy by increasing the rigidity of the structure. 3 s.p. f-ly, 3 ill.

Description

The invention relates to the field of optical instrumentation, in particular to devices for assembling optical components, as well as for assembling and centering lenses in frames.

A technical solution is known for autocollimative centering of a lens in a frame (Journal "Assembly in mechanical engineering and instrumentation", 2010, No. 1, p. 8). Centering of the lens surfaces is carried out by the method of successive approximations. However, as practice shows, the number of such approximations can be on the order of tens, which greatly increases the complexity of the lens centering process.

A known method of centering using a device for autocollimative centering of a lens in a frame (SU No. 972293 A1, class IPC G01M 11/00, 1982), in which, in order to reduce the complexity of the lens centering process, automated systems are used, including automated cartridges with servos, blocks selection, signal processing, the formation of control signals. This allows for automated centering by the method of successive approximations, however, at the same time, the cost of equipment and, therefore, the lens itself increases significantly.

A known method of autocollimation centering of a lens in a frame (Efremov A.A. et al. Assembly of optical instruments. M: Higher school, 1978, p. 146-149).

The lens in the frame is installed in the spindle of the lathe using a centering chuck having a housing with a Morse cone, shear and rotary parts. An autocollimation tube L.A. is installed in the tailstock of the machine Zabelina, which is designed to create a beam of rays with the image of a crosshair (grid) of the diaphragm and allows you to simultaneously project this image onto a centered surface and observe its reflection.

The lens is mounted so that the center of curvature of the surface of the lens closest to the Zabelin tube lies in the same plane as the center of curvature of the rotary part of the cartridge. This coincidence is ensured by choosing the length of the technological part of the frame or using distance bushings.

The mismatch of the center of curvature of the lens surface with the axis of rotation of the spindle is observed as the beating (during rotation of the spindle) of the mesh pattern of the Zabelin tube diaphragm formed by a beam of rays reflected from the lens surface.

At the first stage of centering, the shear part of the cartridge is moved by the required amount, eliminating the runout of the image of the diaphragm grid, i.e. combining the center of curvature of the first surface of the lens with the center of curvature of the rotary part of the cartridge.

At the second stage, the Zabelin tube (or its lens) is moved to the position at which the image of the diaphragm grid is reflected, reflected from the second surface of the lens. By moving the rotary part of the centering cartridge by a certain angle, the runout of the diaphragm grid image is eliminated, that is, the center of curvature of the second lens surface is combined with the axis of rotation of the spindle. Moreover, due to the concentricity of the spherical surfaces of the cartridge and the first lens surface, the coincidence of the center of curvature of the first lens surface with the center of curvature of the rotary part of the cartridge is not violated. The optical unit is ready for turning the outer surface of the frame coaxially with the optical axis and trimming the ends perpendicular to it.

The disadvantage of this technical solution is the difficulty of using it in cases where the lens surface closest to the Zabelin tube is impossible or impractical to use as the first centering surface. Such a situation often develops when centering glued two- or three-component lenses.

In such cases, the refraction of the rays on the surface (surfaces) located between the Zabelin tube and the first centered surface leads to the fact that the autocollimation point of the centered surface (the point at which the reflected image of the diaphragm is projected), observed through the tube, does not coincide with the center of curvature of the surface .

Then, when the rotary part of the cartridge is displaced (the second centering stage), the rotation of the lens aligns the autocollimation point of the second centered surface with the axis of the spindle, and the center of curvature of the first centered surface remains unbiased, but the autocollimation point of the first centered surface observed in the Zabelin tube shifts. There is a need to re-center the lens.

A known cartridge for centering the lenses in (SU 1149201 A1, IPC G02B 7/16, publ. 04/07/1985) containing a shank carrying a swing unit with a base and a movable part in the form of a cylinder, moved by screws. The device comprises an offset unit in two mutually perpendicular directions and a swing unit rigidly connected to the offset unit, and is characterized in that, in order to expand the range of radii of the centering lenses and improve centering accuracy, the swing unit is made in the form of three parallel mounted plates located in the housing, movable in the radial direction and interconnected by means of two shoulders levers and hinges, an orienting rod for fixing the adapter, guide and adjusting screws, p and orienting this rod is fixed in the two extreme faceplate, the faceplate center is located in a guide mounted on the housing movably along its axis of rotation, the levers are hinged in the housing, and the adjusting screws interacting with one of the chucks.

Also known is a cartridge (RU 2442124 C1, IPC G01M 11/00, G01B 11/27, publ. 11/29/2010) for centering lenses in frames, comprising a displacement unit in two mutually perpendicular directions and a rocking unit rigidly connected to the displacement unit. The cartridge is used in the method of centering the lens with a centering cartridge with a shift and rotary parts, mounted in the spindle of the lathe, and a Zabelin tube mounted in the tailstock of the machine, which includes sequentially centering each of the lens surfaces relative to the axis of rotation of the spindle by first moving the shear part the cartridge perpendicular to the axis of rotation of the spindle, then moving the rotary part of the cartridge around the center of curvature of the rotary part of the cartridge. Moreover, when centering a multicomponent lens, based on structural or technological considerations, one of the lens surfaces is selected, the lens is mounted so that, by choosing the length of the technological part of the frame or using remote bushings, the autocollimation point of the selected surface lies in the same plane as the center of curvature of the rotary part of the centering cartridge, lying on the axis of rotation of the spindle, then combine the autocollimation point of the selected surface with the center of curvature of the rotary part of the prices rirovochnogo cartridge shear movement of the cartridge, then combine with the axis of rotation of the spindle autocollimation point other surface of the lens holder by moving the rotary part while maintaining constant the position of the selected point autocollimation lens surface previously combined with the center of curvature of the rotating part of the cartridge.

The disadvantages of the above known cartridges for centering lenses in frames are:

limited range of radii of curvature of centered lenses;

the impossibility of observing autocollimation glare from both surfaces of the lens from an opaque material in visible light (silicon, germanium, etc.).

a significant length of the cartridge, which leads to a decrease in the alignment accuracy due to the deflection of the structure during processing of the frame.

The objective of the utility model is to eliminate and minimize these shortcomings, simplify and reduce the amount of operator work, as well as increase the centering accuracy.

The technical result of the utility model is to expand the functionality of the centering cartridge by providing an increase in the range of radii of the centering lenses and working on both surfaces of the lenses, including material that is opaque in the visible light, and improving centering accuracy by increasing the rigidity of the structure.

The specified technical result is achieved in that in a lens centering cartridge containing a housing with a shear part for movement in two mutually perpendicular directions and a rotary part associated with the shear part, the rotary part is made in the form of a spherical washer, the shear part in the form of a face plate, with in this case, central coaxially oriented through holes are made in the housing, the spherical washer and the faceplate, and the body itself is placed between the spherical washer and the faceplate, which are interconnected by the springs and tension, pressing these washers to the middle part of the housing in the direction of the common axis of the holes.

In addition, on the spherical washer and faceplate, mounting threads are made to fix the cartridge on the machine on either side and install the adapters of the centered lenses.

In addition, adjusting screws are installed in the housing to move the faceplate and rotate the spherical washer.

In addition, the distance between the free ends of the spherical washer and faceplate is less than the diameter of the housing.

The utility model is illustrated by drawings.

In FIG. 1 shows the design of a lens centering cartridge.

In FIG. 2 is a front view of the through hole.

In FIG. 3 shows a lens in a frame with a technological shank and adapter.

The cartridge for centering the lenses contains a housing 1 with a shift part 2 for moving in two mutually perpendicular directions and a rotary part 3 associated with the shift part 2, the rotary part 3 is made in the form of a spherical washer 4, the shift part is in the form of a faceplate 5, while in the case 1, the spherical washer 4 and the faceplate 5 have central coaxially oriented holes 6, and the housing 1 is located between the spherical washer 4 and the faceplate 5, which are interconnected by tension springs 7, pressing these washers to the middle part of the core pus 1 in the direction of the common axis of said openings 6.

On the spherical washer 4 and the faceplate 5, landing threads 8 are made for fixing the cartridge on the machine on either side and installing adapters 9 of centered lenses 10.

Adjusting screws 11 are installed in the housing 1 to move the faceplate 5 and rotate the spherical washer 4.

The distance between the free ends of the spherical washer 4 and the faceplate 5 is less than the diameter of the housing 1.

Thus, in general, the cartridge consists of a housing 1, a displacement unit and a swing unit.

The movement unit is made in the form of a spring-loaded faceplate 5, which is displaced in the housing 1 by adjusting screws 11 with an internal hexagon in two mutually perpendicular directions.

The swing unit is made in the form of a spherical spring-loaded washer 4, and the springing is carried out by tension springs 7, connecting the washer 5 of parallel movement and the washer of rotation 4. The rotation of the spherical washer 4 is carried out directly by screws 11.

In the washers of the displacement and swing units, an internal thread 8 of the same size is made, which allows the cartridge to be fixed on the machine on either side.

The process of centering the lenses using the described cartridge is as follows:

a centered lens 10 in a frame with a technological shank 12 and an adapter 9, ensuring the coincidence of one of the centers of curvature of the surfaces of the lens 10 with the center of curvature (radius R *) of the spherical faceplate 4 of the cartridge (Fig. 3) is fixed in a cartridge mounted in a spindle (not shown) the machine (either from the side of the offset unit or from the side of the swing unit);

observing into the eyepiece of an autocollimation microscope (not shown) an image of an autocollimation flare from the lens surface, the center of curvature of which is aligned with the center of curvature of the cartridge, the screws of the transverse movement unit of the cartridge combine the image with the axis of rotation of the spindle;

then the autocollimation microscope is refocused on the image of the autocollimation flare from the second lens surface and the screws combine the image with the axis of rotation of the spindle with the screws of the cartridge swing unit;

the position of the image of the autocollimation glare from the first surface is controlled and, if necessary, the position of the glare is adjusted to provide a given tolerance for centering the lens surface;

similarly, the alignment of the second lens surface is adjusted;

after combining the autocollimation glare from both surfaces of the lens with the axis of rotation of the machine spindle with a given tolerance, the outside diameter of the rim is grooved to a predetermined size, the rim of the rim of the rim is provided to ensure a given distance from the end to the top of the lens surface and the length of the rim from the technological shank.

The structural features of the device indicated above and reflected in the formula of the utility model ensure that

1) the cartridge is made bilateral, i.e. has the same connecting thread on both sides and can be mounted on the machine both from the side of the movable and from the side of the rotary part, which greatly expands the range of radii of the centered lenses;

2) the internal cavity of the cartridge is made through, which allows for auto-collimation from both surfaces of the lens, including material that is opaque in visible light;

3) the cartridge contains a minimum number of parts, which increases the rigidity of the structure, as well as special elements - spring-loaded washers, providing increased accuracy and reducing the relative length of the cartridge, usually not exceeding 2/3 of the diameter of the cartridge.

Thus, when using the utility model, a technical result is achieved, which is the expansion of the functionality of the centering cartridge by providing an increase in the range of radii of the centering lenses and working on both surfaces of the lenses, including material that is opaque in visible light, and improving centering accuracy by increasing structural rigidity.

Claims (4)

1. A cartridge for centering the lenses, comprising a housing with a shear part for moving in two mutually perpendicular directions and a rotary part associated with the shear part, characterized in that the rotary part is made in the form of a spherical washer, the shear part in the form of a face plate, while central coaxially oriented through holes are made to the housing, the spherical washer and the faceplate, and the housing itself is located between the spherical washer and the faceplate, which are interconnected by tension springs, pressing these to the middle part of the body in the direction of the common axis of said openings. 2. The cartridge according to claim 1, characterized in that the spherical washer and faceplate are made with thread for fixing the cartridge on the machine on either side and installing adapters of centered lenses. 3. The cartridge according to claim 1, characterized in that the housing has adjusting screws for moving the faceplate and turning the spherical washer. 4. The cartridge according to claim 1, characterized in that the distance between the free ends of the spherical washer and the faceplate is less than the diameter of the housing.

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