RU2542636C1 - Method for centring lens in holder and holder therefor - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method includes mounting a lens on the flat shoulder of the intermediate part of a holder, placed on the shoulder of the cylindrical opening of the main holder and capable of tilting. The method includes rotating the main holder about its reference axis, measuring the beat of the centre of curvature of the first working surface of the lens relative to the axis of rotation thereof, tilting the intermediate part to align the centre of curvature of the first working surface of the lens with the axis of rotation and fixing the position of the intermediate part; measuring the beat of the beat of the centre of curvature of the second working surface of the lens relative to the axis of rotation; shifting the lens on the flat surface of the supporting shoulder to align the centre of curvature of the second working surface of the lens with the axis of rotation and fixing the position of the lens in the intermediate part of the holder. The holder has an external cylindrical base surface and a flat external base flange which form the reference axis of the holder, an internal cylindrical opening with a supporting shoulder in which the intermediate cylindrical part is inserted with an increased seating clearance, said intermediate cylindrical part having a flat supporting shoulder for mounting the lens. The intermediate cylindrical part is mated with the supporting shoulder of the internal cylindrical opening on a spherical surface.

EFFECT: high centring accuracy owing to centring on both surfaces of the lens.

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Description

The invention relates to the field of optical instrumentation and can be used to center lenses in frames during assembly.

When assembling and then fixing (fixing) the lens in the frame, it is necessary to ensure the correct location of the working surfaces of the lens relative to the base axis of the frame. The base axis of the frame is the axis of its outer cylinder, perpendicular to one of the flat surfaces of the outer flange of the frame selected for the base surface. If the working surfaces of the fixed lens are spherical (convex or concave), then both centers of curvature of these surfaces (defining the optical axis of the lens) should be located on the base axis of the frame, and if one of the working surfaces of the lens is flat, it should be perpendicular to the base axis frames. In these cases, the lens will be centered relative to the frame. However, due to numerous technological errors in the manufacture of the lens and the frame, the lens will have a decentration, which will subsequently lead to aberrations of the lens system.

The alignment of the lens (or reduction of its possible decentration) in the frame is performed during the assembly of the lens and the frame using alignment. Two methods of such adjustment are known, which are described in monographs and textbooks: G. Pogarev Alignment of optical instruments. - L., Mechanical Engineering, 1982, p. 32-35; Elnikov N.T., Ditev A.U., Urusov I.K. Assembly and adjustment of optical-mechanical devices. - M., Mechanical Engineering, 1974, p.107-111; Efremov A.A. and other assembly of optical devices. - M., Higher School, 1978, p. 145-148; CM. Latyev Designing accurate (optical) instruments. - SPb., Polytechnic, 2007, p. 57-60.

The first method of centering (autocollimation) is that the lens is first fixed in one way or another in the frame, which is performed with allowances for the outer dimensions, then the frame is fixed in the centering ("floating") cartridge of the machine, the centers of curvature of the lens are combined using a centering cartridge and an autocollimator with the axis of rotation of the spindle of the machine and cutter the outer (base) surface of the frame in nominal dimensions. Special machines (stations) have now appeared where the process of this centering method is automated (see the article by S. M. Latyev, D. M. Rumyantsev and P. A. Kuritsyn, “Design and Technological Methods for Aligning the Lens Systems.” Optical Journal , No. 3, 2013, p. 92-96).

The disadvantages of this method of alignment is: the need to use special sophisticated equipment, alignment errors due to the influence of cutting forces, as well as the "pollution" of the workplace during processing of the frame.

The second method of centering is based on the fact that the lens is mounted in a frame, the base outer surfaces of which are made in a nominal size, with an increased clearance in the fit for the ability to move or tilt the lens during fixing to align its center of curvature with the base axis of the frame, rotating the latter around base axis. This method is used when fixing the lens in the frame by rolling or gluing. Currently, there are also stations to automate the process of such centering. The scheme and operation of one of these OptiCentric stations, manufactured by TRIOPTICS (http://www.trioptic. Com Automated Centering and Bonding Machine), is presented in an article by S.M. Latyeva, D.M. Rumyantseva and P.A. Kuritsyna "Design and technological methods for ensuring the alignment of lens systems." Optical Journal, No. 3, 2013, pp. 92-96.

This method of centering the lens in the frame at this station is selected as a prototype.

The lens alignment is carried out as follows: the lens barrel on the outer base cylinder and the base flange is fixed in the cartridge of the axis of rotation of the spindle of the station; then install the lens of one of the working surfaces (supporting) on a flat supporting flange of the cylindrical hole of the frame; lead in rotation of the cartridge with a frame around its base axis; measure the runout of the center of curvature of the second working surface of the lens relative to the axis of rotation using an autocollimator; carry out a radial shift of the lens along the surface of the support flange in the increased landing clearance along the cylindrical hole of the frame to align the center of curvature of the second working surface with the axis of rotation; fix the position of the lens in the frame. The fixing of the lens in the frame can be carried out, for example, by quick-setting adhesive under the influence of ultraviolet radiation.

The main disadvantage of this method of centering the lens in the frame is that here only one (second) working surface of the lens is centered. If the support flange of the cylindrical hole of the lens mount is not perpendicular to the base axis of the mount or the hole in the mount is eccentric to the base axis, then the center of curvature of the first (support) surface of the lens will not coincide with the axis of rotation, i.e. will be decentered.

The problem to which the invention is directed is to increase the accuracy of alignment of the lens in the frame, which is achieved by achieving a technical result, which consists in providing the possibility of centering on both surfaces of the lens.

The technical result is achieved by the fact that in the centering method, including the possibility of rotation of the lens barrel around its base axis, the installation of the lens of one of the working surfaces on the support flange of the cylindrical hole of the barrel, the rotation of the frame around its base axis, measurement of the runout of the center of curvature of the second lens working surface relative to axis of rotation with the help of an autocollimator, radial shift of the lens along the surface of the support collar in the enlarged clearance of the fit of the cylindrical hole of the frame for aligning ntra of the curvature of the second working surface with the axis of rotation and fixing the position of the lens in the frame, it is new that the lens is mounted on a flat shoulder of the intermediate part, placed on the shoulder of the cylindrical hole of the main frame and having the ability to tilt relative to it, rotating the main frame around its base axis, measure the runout of the center of curvature of the first working surface of the lens relative to the axis of rotation, tilt the intermediate part of the frame to align the center of curvature of the first working surface of the lens with the axis rotation, fix, for example, with quick-hardening adhesive, the position of the intermediate part of the frame relative to the main, measure the runout of the center of curvature of the second working surface of the lens relative to the axis of rotation, shift the lens radially along the flat surface of the supporting collar of the intermediate part of the frame to align the center of curvature of the second working surface of the lens with the axis of rotation and fix the position of the lens in the intermediate part of the frame.

A lens barrel having an outer base cylindrical surface and a flat outer base flange forming the base axis of the rim, an inner cylindrical hole with a supporting shoulder, is characterized in that an intermediate cylindrical bearing with an increased clearance clearance is inserted into the inner cylindrical hole with a supporting shoulder, and the intermediate cylindrical bearing on the supporting shoulder a part equipped with a flat supporting collar for mounting the lens, the intermediate cylindrical part mating with the supporting collar of the inner cylindrical from a verst on a spherical surface.

The coupling of the intermediate cylindrical part of the frame with the supporting flange of the cylindrical hole of the frame on a spherical surface can be accomplished, for example, by making the outer part flange spherical of the intermediate part or spherical of the supporting flange of the opening of the main frame.

This solution allows you to center the lens relative to the base axis of the frame, not only on one working surface, but also on the second. By tilting the intermediate part of the frame around the center of curvature of the supporting spherical flange of the outer surface of the intermediate part of the frame, or the spherical surface of the supporting flange of the inner hole of the main frame, the center of curvature of the first (supporting) working surface of the lens is shown on the base axis of the main frame or, if this surface is flat, it is installed perpendicular to the base axis. The control is carried out by an autocollimator, which focuses on the center of curvature of the first surface of the lens, or adjusts to control the runout of a flat surface. The centers of curvature of the supporting surface of the lens and the spherical flange of the intermediate part of the frame (or the spherical supporting flange of the main frame) should not lie in the same plane, which is easily ensured by setting the corresponding value of the radius of the flange. Fixation (fixing) of the intermediate part of the frame in the main can be carried out in various ways, for example, by quick-curing glue under the influence of ultraviolet radiation.

The second working surface, as in the prototype, is centered by a radial lens shift, but along the supporting flange of the intermediate part of the frame. Moreover, if the bearing surface of the lens is spherical, then the lens tilts around the center of curvature of the supporting surface (which was already aligned with the base axis by tilting the intermediate part of the frame) until the center of curvature of the second surface is aligned with the base axis of the main frame. If the supporting surface of the lens is flat, then the center of curvature of the second surface is displaced perpendicular to the base axis until it is aligned with it. After this operation, the position of the lens is fixed in the intermediate part of the frame.

Thus, both centers of curvature of the working surfaces of the lens are brought to the base axis of the frame, which is required to center it.

The essence of the invention is illustrated by figures, which represent both the possibilities of pairing the intermediate part with the supporting shoulder of the cylindrical hole of the frame.

Figure 1 shows the main frame 1 having a base cylindrical surface B and a flat base surface A, which form the base axis of the frame O ₁ -O ₂ , as well as a flat supporting flange of the inner hole. A cylindrical intermediate part 2 of the frame is inserted into the cylindrical hole of the main frame with a gap, the outer supporting surface of which is made spherical with the center of curvature C _о , mating with the flat supporting flange of the main frame 1.

A lens 3 having a supporting (first) working surface G with a center of curvature C _g and a second working surface B with a center of curvature C _{c is} inserted on the flange of the inner cylindrical hole of the intermediate part 2 of the frame with a gap.

Figure 2 shows the main frame 1, having a base cylindrical surface B and a flat base surface A, which form the base axis of the frame O ₁ -O ₂ , as well as a spherical support flange of the inner hole with a center of curvature With _about . A cylindrical intermediate part 2 of the frame is inserted into the cylindrical hole of the main frame with a gap, the outer supporting surface of which is made flat, mating with the spherical supporting flange of the main frame 1.

A lens 3 having a supporting (first) working surface G with a center of curvature C _g and a second working surface B with a center of curvature C _{c is} inserted on the flange of the inner cylindrical hole of the intermediate part 2 of the frame with a gap.

The proposed method of centering the lens in the frame is implemented as follows: the lens 3 is installed in the intermediate part 2 of the frame and, for example, is filled with quick-hardening glue around the perimeter; then the intermediate part 2 of the frame is installed in the main frame 1 and is also filled around the perimeter with quick-setting adhesive; further, the main frame 1 on the base surfaces A and B is fixed in the cartridge of the centering station and rotated around the base axis coinciding with the axis of rotation of the cartridge O ₁ -O ₂ ; measure, for example, using a photoelectric autocollimator, the runout of the center of curvature C _{g of the} working surface G of the lens; acting by the force F ₁ on the intermediate frame, for example, by a piezomanipulator, tilt the intermediate part of the frame around the center of curvature C _about until the center of curvature C _{g of the} lens is compatible with the axis of rotation O ₁ -O ₂ ; fix (fix) the position of the intermediate part 2 of the frame in the main 1, for example, illuminating the adhesive with UV radiation. Next, they proceed to centering the second surface of the lens, for which the beat of the center of curvature C _{in the} working surface B of the lens is measured using an autocollimator; acting by force F ₂ on the lens with a piezo manipulator, tilt the lens around the center of its curvature C _g until the center of curvature C _{in the} lens is aligned with the axis of rotation O ₁ -O ₂ ; fix (fix) the position of the lens in the intermediate part 2 of the frame, illuminating the adhesive with UV radiation.

Thus, the centers of curvature C _g and C _in both surfaces of the lens are located on the base axis O ₁ -O _{2 of the} main frame 1, i.e. the lens is centered in the frame.

The proposed method of centering the lens in the frame and the design of the frame can improve alignment accuracy by centering both working surfaces of the lens relative to the base axis of the frame, as well as to automate the process of centering both surfaces.

Claims (3)

1. The method of centering the lens in the frame, including installing the lens of one of the working surfaces on the supporting flange of the cylindrical hole of the frame, rotating the frame around its base axis, measuring the runout of the center of curvature of the second working surface of the lens relative to the axis of rotation using an autocollimator, radial shift of the lens along the surface of the supporting flange in the enlarged landing clearance along the cylindrical hole of the frame for combining the center of curvature of the second working surface with the axis of rotation and fixing the position of the lens in the frame, from characterized in that the lens is mounted on a flat shoulder of the intermediate part, placed on the shoulder of the cylindrical hole of the main frame and having the ability to tilt relative to it, rotating the main frame around its base axis, measure the runout of the center of curvature of the first working surface of the lens relative to the axis of rotation, tilt the intermediate part of the frame to combine the center of curvature of the first working surface of the lens with the axis of rotation, fix the position of the intermediate part of the frame relative to the main one, measure the heartbeat e of the center of curvature of the second working surface of the lens relative to the axis of rotation, shift the lens in the radial direction along the flat surface of the supporting shoulder of the intermediate part of the frame to align the center of curvature of the second working surface of the lens with the axis of rotation and fix the position of the lens in the intermediate part of the frame. 2. A lens barrel having an outer base cylindrical surface and a flat outer base flange forming the base axis of the rim, an inner cylindrical hole with a support shoulder, characterized in that an intermediate resting on the support shoulder is inserted into the inner cylindrical hole with a support shoulder with an increased landing clearance a cylindrical part equipped with a flat supporting collar for mounting the lens, the intermediate cylindrical part mating with the supporting collar of the inner cylindrical holes on a spherical surface. 3. The lens barrel according to claim 2, characterized in that the coupling of the intermediate cylindrical part of the frame with the supporting flange of the cylindrical hole of the frame on a spherical surface can be carried out, for example, by making the outer part flange spherical of the intermediate part or spherical of the supporting flange of the main frame opening.

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