SU1101771A1 - Oil immersion microscope lens - Google Patents

Abstract

LENS OF OIL IMMERSION MICROSCOPE, containing four factors, the first of which is a flat-convex lens, the second is a single positive meniscus facing the object, and the third and fourth glued positive lens consisting of a neutral and positive lens, which is a drawing subject with a drawing and a drawing. correction of chromatism magnification, for the fourth component, a glued composite component is introduced, consisting of plane-convex and concave flat lenses, with the coefficient of average dispersion of the concave flat lens being greater than average coefficient / 1the dispersion of a convex lens.

Description

The invention relates to optical instrument making, namely to immersion lenses of microscopes, and can be used in various microscopes and as an objective for micrographs. The oil-immersion objective lens OM-20, 90X1.30, is known, consisting of a flat-convex lens, a single positive meniscus, two glued and two three-glued components l. . The disadvantages of this lens are residual chromatism of magnification reaching 2% at the edge of the floor, which necessitates the use of compensating eyelets, more complex construction compared to conventional ones, and the impossibility of using the lens for microphotographs. OM-41 microscope oil immersion lens is also known , 90X1.25 consisting of a convex lens, a positive meniscus and two two-curved components 2. The disadvantages of such an objective are the residual chromatism of magnification, reaching 2% at the edge of the field and, as a consequence, the inability to use the objective for micrographs. A microscopic lens of oil immersion OX-32, 100X1.25, is known, containing four components, the first of which is a flat lens, the second is a single positive MieHKCK facing the object, and the third and fourth glued positive lens consists of a positive one Noah lenses The disadvantages of the known lens are the presence of xrsmatism of the increase at the edge of the floor (about 2%), which requires the use of compensatory eye-glasses of a complex construction, and the impossibility of using the lens for microphotography. The aim of the invention is to improve chromatism correction. The goal is achieved by the fact that in the objective lens of an oil immersion microscope, containing the component's chtof, the first of the KOTOE "JX flat convex lens, the second is a single positive meniscus, concavity to the object and the third and fourth are glued positively a lens consisting of negative and positive lenses, after the fourth component, a glued component is introduced, consisting of plane-convex and concave-flat lenses, with the coefficient of mean dispersion in The flare lens is larger than the coefficient of the average dispersion of the plane-convex lens. The drawing shows the principal optical layout of the lens. The lens consists of successively along the beam of the frontal flat-convex lens 1 of a single positive meniscus 2 and two double-glued positive components 3 and 4, behind the latter of which is glued component 5, consisting of flat convex b and concave 7 lenses. a frontal flat convex lens 1 and a positive meniscus 2 serve to reduce the numerical aperture for the subsequent part of the lens. The glued components 3 and 4 compensate for the aberrations introduced by the frontal part and also provide the scale of the image. The layout of the objective scheme of the four indicated components provides an increase in chromatism of the order of 2%, which requires the use of compensating eyes. The introduction of the glued component S behind the last component of the lens makes it possible to correct the chromaticism of the magnification in the lens, which in turn makes it possible to use Huygens or Kalnar type ovular eyelets with already existing immersion lenses. Usually, in microscopic lenses that are used {Together with compensatory eyepieces, the chromatism of the magnitude of the order of 2% is left so as not to complicate the design of the lens, and the oculum E is stretched. . read in such a way as to their. the increase chromatism was the opposite sign. Thus, compensation X1} with 4aizm of magnification is obtained. on the scale of the image. The compensator works from a finite distance and has a rendered INPUT pupil. With the same design (the first lens is a flat glass, the second is a concave plane), depending on the ratio between the coefficients of the average dispersions, 2 or 2 optical materials from which the lenses are made, a compensator can be obtained, which either introduces a negative (anomalous compensator ), or a positive increase chromatism (normal compensator). Thus, in order to compensate for the positive magnification lens chromaism, it is necessary to use an anomalous compensator, i.e. it is necessary that the coefficient of the average dispersion of a concave plane lens be greater than the coefficient of the average dispersion of the plane-convex linea.

The lens has a magnification of 99, b, the numerical aperture of Ar1.25, the focal distance i 1.89 mm. Chromatism increase on the edge of the floor - 0.5%.

Compared with the lens known in the proposed lens, the magnification chromaticism is 4 times better, which will allow using simple eyepieces and applying a lens for microphotography.

The use of the proposed lens as compared with the base object will allow reducing the assembly of optical microscopes, using simpler eye-glasses, as well as using a micro-lens for micrographs.

Claims (1)

OIL IMMERSION MICROSCOPE LENS, containing four components, the first of which is a plano-convex lens / the second is a single positive meniscus facing concavity to the subject, and the third and fourth are glued positive lens consisting of negative and positive lenses, characterized in that, in order to improve correction chromatism increase; behind the fourth component, a glued component is introduced, consisting of a plano-convex and concave plane lenses, the coefficient of a flat middle lens. the concave line average dispersion is greater than the plane convex dispersion coefficient