SU531023A1 - Method of controlling lens centering in cartridge - Google Patents

Description

(54) METHOD OF CONTROL OF CENTERING THE LENSES IN THE PATRON

A lens 2 is attached to the cartridge 1 in a known manner, and a light beam from the laser 4 operating in a single-mode mode is directed to it through the beam splitting plate 3 along the spindle axis. Reflected from the surfaces of the lens beams first fall on the beam-splitting plate 3, then on the screen 5, where when they are superimposed, an interference pattern is formed. If the cartridge is brought into rotation, then if the optical axis of the lens is not precisely aligned with the axis of the spindle, a light spot is seen on the screen, making a circular motion (beating). With precise alignment, the light spot remains stationary and has the form of a ring system of interference fringes.

If the beating is small, then the presence or absence of it is difficult to determine. This difficulty is due, firstly, to the fact that the borders of the light spot are unsharp, and. secondly, due to the fact that the distance from the lens to the screen cannot be large according to the conditions of use.

To increase the sensitivity to the beating of the device under consideration, it is necessary for the screen plane B to place a transparent copy of the interference pattern formed as a result of the reflection of the laser beam from the surfaces of the centered lens. Such a copy is easy to make a photo path by placing the film in the plane of the screen. When a real interference pattern is superimposed on its copy, a system of straight moire fringes is formed, the width of which is connected with the parameters of ring patterns by the following dependence;

ъ

26

where Q is the radius of the central interference ring,

cf is the distance between the centers of two ring systems.

It follows from this dependence that, for the same d d, the width of the band varies the more, the closer the centers of the interference patterns are from each other. This property, when centering lenses, is used as follows.

First, the optical axis of the lens is aligned with the axis of the shpindl by observing the glare on the screen to achieve its lowest beating. Then a copy of the interference pattern is superimposed on each other.

pictures and flare, striving to get wide moire stripes. The overlay can be performed either by the corresponding movements of the screen or by tilting the beam-splitting plate 3. After this operation, the alignment of the axes is refined, so as to change the width of the moire strips when the spins are rotating.

The method is appropriate to use in mass and mass production. If necessary, it can also be used to center individual lenses.

The sensitivity of the method does not depend on the distance of the lens to the screen. For this reason, the installation used for its implementation may be compact and located at a place convenient for operation.

The application of the method will improve the quality of, for example, systems such as objects of telescopes, geodesic, collimator and other commonly used devices.

gaining

Formula

The method of controlling the centering of the lenses in the 30 cartridge, which consists in sending a beam of rays to the controlled lens, perceives the rays reflected from its surfaces, which by means of a projection system direct to the screen, so that that, in order to increase the accuracy of the angular and parallel alignment of the optical axis with the axis of the cartridge, a transparent copy of the interference pattern, formed from both lens surfaces, is placed in the plane of the screen, the lens is moved in the cartridge so that the moire bands arising When the interfering pattern was superimposed on its copy, they had the greatest width and minimum mobility, and the controlled value was estimated from the change in the width of these bands.

Sources of information taken into account in the examination;

1.Bardin A.A. Optical glass technology. Higher School 1963, p. 382393.

2. Zakharievsky A.I. Interferometers7 Oborongiz, 1956, pp. 179-180.