SU781736A1 - Microobjective lens - Google Patents

Description

The invention relates to optomechanical npH6opoctpoeHHra and can be used, for example, in metallographic and ore microscopes. five

Microscopic lenses operating in a bright field will be known. Ll. A significant influence on the image quality of such microscopic lenses is exerted by scattered light, which is formed due to 10 single reflections from the optical surfaces of the lens (the so-called Bje first-order reflections). In a number of cases, reflexes can reduce the contrast of iso-angiography so much that observation of the fine structure of a weakly reflecting object becomes impossible even when using a lens with perfect correction of aberrations.

Thus, when developing a micro-lens of reflected light, in addition to a good correction of aberrations, special attention must be paid to eliminating harmful scattered light of the 1st order from the surfaces of the lenses (reflec-25 owl).,

Micro-lenses of reflected light are known, where a reduction in the coefficient of illumination is achieved due to the fact that part of the lens is about

The entire kit for the lenses is placed in the microscope tube and, not participating in the work of the lighting system, does not form first-order reflexes 2.

However, these lenses are structurally made quite complex, consisting of a large number of lenses. In addition, such micro lenses are not interchangeable with existing micro lenses and cannot be used in already existing microscope models.

The closest in design and performance is the lens.

The lens contains an image curvature compensator, made in the form of a meniscus, aligned with the object, and two positive components located behind the curvature compensator, separated by an air gap. With etch, the first positive component, located directly behind the curvature compensator, is made in the form of two positive single lenses: a meniscus facing away from the object and a two-convex lens, and the second positive component is in the form of a glued lens

However, the micro-lens has significant reflections from optical surfaces, which leads to a deterioration of the contrast of the image.

The chromatism of the increase in microobjects reaches a value of 1.86%, which necessitates the use of special compensating eyelets and observes the observation conditions when using scales or grids. In addition, OPH-12 micro-lens has insufficient chromatic correction of aberrations of the axial point of the object.

The aim of the present invention is to create a reflected-light microobjective with reduced chromatism of magnification and improved chromatic correction of the image of the axial point of an object that has sufficiently small reflections of the first mode, which provides high image contrast, pleasantness and convenience of observing and researching weakly reflecting objects.

The goal is achieved by the fact that before the curvature compensator an image is set to a positivally frontal, the first surface of which is flat and the second aplanatic, the image curvature compensator is in the form of a glued meniscus with external aplanatic surfaces facing the concavity to the object, while the optical power of the curvature compensator is 0.5–0.7 microscopic optical power; the difference between the dispersion coefficients of lens glass and the curvature compensa- tion is at least 15, and the positive comp Onent, placed directly behind the 1RCHYE1NY EE1P6 lnen compensator, is in the form of a QOKbz of an oblique glued lens.

The drawing shows the optical layout of the proposed lens.

The micro-lens consists of a positive frontal lens 1, a compensator 2 of the curvature of the images and two positive glued components 3 and 4, separated by an air gap.

Frontal lens 1 is a single flat-convex lens with an aplanatic second surface. The image curvature compensator 2 is made in the form of a glued meniscus of negative lens 5 and

positive lens 6 facing inward towards the object, with the first 7 and third 8 meniscus surfaces aplanatic. The difference in the dispersion coefficients of the lenses 5 and 6 is at least 15. The ratio of the optical power of component 2 to the optical power of the lens is 0.5-0.7. The positive component 3 includes a positive lens 9 and a negative lens 10, and the surfaces C and 12 are convex. The positive component 4 includes a negative lens 13 and a positive 14. The circuit contains the plane of the object 15 and the aperture diaphragm 16 located in the back focal plane of the micro-lens.

Claims (3)

1. Panov V.A. and others. Optics of microscopes. L., Mechanical Engineering, 1976, p. 112 2. US patent 3428389, CL 350-117, 1969. 3. Skvortsov G.E. and other Microscopes, l., Mashinostroenie, 1969, p.210-211 (prototype). $ n s y to / 7 and g