RU44184U1 - RADIATION DIRECTION FILTER (OPTIONS) - Google Patents

Abstract

The utility model relates to the field of designing transceiver, for example, optical devices containing protective hoods, and can be used in optics, astronomy, for protecting television screens, monitors, and optical sights.

The radiation direction filter according to the first embodiment includes a housing in the form of a hood with a degenerate internal surface of the second order, which are formed parallel to the axis of the filter, installed along the radiation rays of the receiving and / or transmitting device. It is equipped with at least one additional hood made in the form of a spiral installed inside the outer hood, and the shortest distance between each spiral turns facing each other is selected to be greater than the largest value of the largest wavelength of the radiation spectrum.

The radiation direction filter according to the second embodiment includes a housing in the form of a hood with a degenerate internal surface of the second order, which are formed parallel to the axis of the filter, installed along the radiation rays of the receiving and / or transmitting device. The hood can be made in the form of a spiral, while the shortest distance between each spiral turns facing each other is selected to be greater than the largest value of the largest wavelength of the radiation spectrum.

Description

The invention relates to the field of designing transceiver, for example, optical devices containing protective hoods, and can be used in optics, astronomy, for protecting television screens, monitors, and optical sights.

A light-shielding hood in the form of a truncated cone or a truncated pyramid is known that protects the lens of a photo or movie camera from side light rays during shooting (see Polytechnical Dictionary, M., Sovetskaya Encyclopedia Publishing House, 1976, p. 56).

A known light-protective hood for optical devices, consisting of a housing and diaphragms, each of which is made in the form of a lateral surface of a truncated cone, the generatrix of which is with an extreme illumination beam for each diaphragm an angle in the range of 80 ... 110, its working edge is on the field boundary view of the optical device, the working edge of each previous diaphragm, counting from the inlet of the hood, lies on the segment formed by the working edge of the subsequent diaphragm and the point of intersection of the boundary of the optical field of view instrument with the line which connects the point of attachment of the diaphragm to the body followed by a hood entry point illumination rays (see. the disclosure of patent RF №2073903, MGTK 6 G 83 B 11/84).

A disadvantage of the known devices is the excess of the angle of illumination of the angle of the field of view of the receiving device or an increase in the scattering angle of the transmitting device, which determines the signal-to-noise ratio.

The objective and the technical result is to improve the quality of the signal-to-noise ratio by reducing the side illumination angle for the receiving device or the scattering angle for the transmitting device.

The specified technical result of the radiation direction filter according to the first embodiment is achieved by the fact that it contains a housing in the form of an outer hood with a degenerate inner surface of the second order, which are parallel to the filter axis, installed inside the outer hood, installed along the radiation rays of the receiving and / or transmitting device, at least one additional hood made in the form of a spiral, while the shortest distance between each spiral turns facing each other is chosen as the largest shego maximum value of the radiation spectrum of wavelength.

In addition, the optional lens hood is aligned with the core.

The specified technical result of the radiation direction filter according to the second embodiment is achieved by the fact that it comprises a housing in the form of a hood with a degenerate inner surface of the second order installed along the radiation rays of the receiving and / or transmitting device, the generators of which are parallel to the filter axis, characterized in that the hood is made in in the form of a spiral, in this case, the shortest distance between each turns of the spiral facing each other is selected to be greater than the largest value of the largest wavelength of the radiation spectrum.

In addition, the degenerate second-order surfaces of the blends are cylindrical.

In the studied and related fields of technology, no devices were detected, as with the claimed combination of essential features, therefore, it satisfies the condition of patentability “novelty”.

The inventive device is illustrated by drawings, in which Fig. 1 shows a section along the axis of the radiation direction filter in the first embodiment, Fig. 2 is a front view of the radiation direction filter in the first embodiment, Fig. 3 is a front view of the radiation direction filter in the second embodiment .

The radiation direction filter according to the first embodiment (Fig. 1,2) consists of an outer hood - a housing 1 mounted on a receiving and / or transmitting device 2, for example, on a lens (not included in the filter design), an additional hood 3 made in the form Archimedes spirals. The coils of the spiral are interconnected by jumpers 4. The inner surface 5 of the outer hood 1 can be separated from the outer surface of the additional hood 3.

The generators of the inner surface 5 of the outer hood 1 and forming the outer and inner surfaces of the additional hood are parallel to the axis 6 of the filter.

The shortest distance “a” between each blended surface facing each other is chosen to be greater than the maximum value of the largest wavelength of the radiation spectrum.

The optional lens hood may be aligned with the outer lens hood. The ratio of the length of the additional hood to the number of turns of the spiral is determined by the purpose of the device for which the filter is intended.

The radiation direction filter according to the second embodiment includes a housing in the form of a spiral hood 3, the spirals of which are interconnected by jumpers 4.

The radiation direction filter in both cases works as follows. The filter is mounted on the receiving or transmitting device, for example, on the lens of an optical device (theodolite, optical sight, laser range finder, etc.).

The received or transmitted radiation passes through the gaps between the outer and the turns of the additional spiral hood. The size of the slots (distance "a") is determined by the above ratio. An additional lens hood (or one lens hood in the second embodiment), as well as the outer one, are made of opaque material.

The use of blends restricts the flow of received or transmitted radiation whose angles exceed the solid angle of the receiving device or limit the scattering angle for the transmitting radiation of the device.

The claimed device can be implemented using known materials and technological methods and, therefore, satisfies the patentability condition "industrial applicability".

Claims (3)

1. The radiation direction filter, including a housing installed in the direction of the radiation of the receiving and / or transmitting device in the form of a hood with a degenerate inner surface of the second order, the generators of which are parallel to the filter axis, characterized in that it is equipped with at least an external hood installed one additional blend made in the form of a spiral, while the shortest distance between each spiral turns facing each other is chosen larger than the largest value of the longest wavelength spectrum but radiation. 2. The radiation direction filter according to claim 1, characterized in that the additional hood is located coaxially with the main one. 3. The radiation direction filter, including the housing installed in the direction of the radiation of the receiving and / or transmitting device in the form of a hood with a degenerate inner surface of the second order, the generators of which are parallel to the filter axis, characterized in that the hood is made in the form of a spiral, while the shortest distance between each spiral coil turned to each other, the largest value of the largest wavelength of the radiation spectrum is selected.