RU2073903C1 - Flare protection lens hood for optical instruments - Google Patents

Abstract

FIELD: optical instruments which protect against flare. SUBSTANCE: device has housing and aperture set, in which each aperture is designed as side surface of cone frustum which generatrix is at angle of 80-110 degrees to extreme flare angle for corresponding aperture, which light edge is located in sight of optical instrument. Light edge of preceding aperture, if counting starts from input aperture of lens hood, is located in straight line piece which is limited with light edge of next aperture and point of intersection of sight border of instrument and straight line which connects point in which next aperture is mounted to hood housing, and point in which flare beams enter. EFFECT: decreased size. 1 dwg

Description

 The invention relates to the field of designing optical devices containing in their composition light-protective hoods.

 A well-known optical hood (V.N. mounted perpendicular to the longitudinal axis of the hood.

 The disadvantage of this hood is that for a given attenuation coefficient of the hood, it has large dimensions in length and a significant number of diaphragms.

 A small-sized (in length) hood is known (see also Fig. 5.7) [2] incorporating a set of flat and annular diaphragms and one conical mounted on the front edge of the hood's inlet.

 The disadvantage of this hood is the complexity of its design and large transverse dimensions.

 The aim of the present invention is to reduce the dimensions of the hood at a given value of its attenuation coefficient.

This goal is achieved in that each diaphragm of the lens hood is made in the form of a lateral surface of a truncated cone, the generatrix of which makes an angle in the range of 80 110 ^o with the limit beam of illumination for this diaphragm, and its working edge is on the border of the field of view of the optical device. The working edge of each previous diaphragm (counting from the inlet of the lens hood) lies inside a straight line formed by the working edge of the subsequent diaphragm and the point of intersection of the visual field of the optical device with a straight line that connects the attachment point of the subsequent diaphragm to the lens hood with the entry point of the light rays.

The drawing shows a General view of such a light shade hood. It consists of a housing 1 and diaphragms 2, 3, 4, 5, 6, 7, 8, made in the form of lateral surfaces of truncated cones. The lens hood is installed in front of the optical device 9, the lens 10 of which has a field of view bounded by the extreme rays 11. The aperture 8 is mounted so that its working edge 12 is located at the boundary of the field of view 11 of the lens 10, and its generatrix is with a limit illumination beam 13 for this the diaphragm falling at an angle A8 to the axis of the lens hood and passing through the entry point of the light rays (point O), an angle in the range of 8 110 ^o .

The diaphragm 7 is installed so that its working edge 14 lies inside the segment BB of the boundary of the field of view 11 of the lens 10 formed by the working edge 12 of the subsequent diaphragm 8 and the point of intersection of the boundary of the field of view 11 of the lens 10 of the optical device 9 with a straight line 16 connecting the entry point rays of illumination (point O) with the point of incorporation of the diaphragm 8 into the housing 1 of the hood. The generatrix of the diaphragm 7 makes up with an extreme exposure beam 16 of this diaphragm incident at an angle A 7 to the axis of the hood and passing through the entry point of the exposure rays (point O), an angle in the range of 80 110 ^o .

The remaining apertures 2 ^o C6 are set as described, and the angles A2 ^o CA6 in the drawing are the limiting angles of illumination of these apertures, respectively.

 The attenuation of light noise in the hood of this design is as follows.

1. If the beam from point O falls on any of the above diaphragms at an angle greater than 90 ^o , then it is reflected either outward, from the hood, or on the inner surface of the previous diaphragm (counting them from the inlet of the hood), and from it or on the inner surface the body of the hood, or on the outer surface of the subsequent diaphragm, and from them again on the outer surface of the previous diaphragm at an angle greater than 90 ^o . As a result, the light beam falls into the trap and loses its energy after repeated reflection.

2. If the beam from point O falls on any of the above diaphragms at an angle less than 90 ^o , it is reflected (crossing the longitudinal axis of the lens hood) onto the outer surface of one of the previous diaphragms, and from it or, as described above, falls into the trap, either reflected from the hood outward.

 The number of aperture, their outer diameters along the length of the hood and the longitudinal dimensions of the hood are determined based on the required attenuation coefficient (determined by the number of beam reflections and the type of surface of the aperture and lens hood), as well as the value of the maximum angle of illumination of the lens hood, equal to the maximum angle of illumination of the last diaphragm.

 Implementation of the proposed design allows the manufacture of lens hoods of smaller dimensions with the same values of their lighting characteristics as for blends with flat diaphragms.

Claims (1)

A light-shielding hood for optical devices, consisting of a body and diaphragms, characterized in that each diaphragm is made in the form of a lateral surface of a truncated cone, the generatrix of which is an angle in the range of 80 110 ^o with the maximum illumination beam, its working edge is at the field boundary view of the optical device, the working edge of each previous diaphragm, counting from the inlet of the hood, lies on a segment formed by the working edge of the subsequent diaphragm and the point of intersection of the visual field boundary an optical instrument with a straight line which connects the point of attachment of the diaphragm to the body followed by a hood entry point illumination rays.