RU69985U1 - DEVICE FOR CONTROL OF THE INCOMPARABILITY OF THE HEAT AND VISION AND VISUAL CHANNELS OF COMBINED SIGHTS - Google Patents

Abstract

The utility model relates to the field of instrumentation, and more specifically to devices for controlling the imbalance of the visual and thermal imaging channels of combined sights. The objective of the utility model is to increase the accuracy of monitoring the imbalance of the visual and thermal imaging channels of the combined sight by providing the ability to control the imbalance of the channels of the optical unit of the device during operation in laboratory and field conditions. The device contains optically coupled mirror collimator (1), including a source of visible (9) and infrared radiation (7), a grid (5) and a mirror lens (4), and a first optical block (2) for pairing the mirror collimator with the visual and thermal imaging channels of the combined the sight installed at the output of the mirror collimator (1), the first and second outputs of the first optical unit (2) are optically connected respectively to the visual and thermal channels of the combined sight, and the first optical A compensator (13), and at the second output there is a protective glass (17) that transmits thermal radiation. New in the device is that the protective glass (17) is installed with the possibility of its output from the path of the radiation beam that has passed the second exit of the first optical unit (2), or is made of a material partially transmitting visible radiation. At the same time, a second optical unit (3) was introduced into the device, including a system of two parallel rigidly coupled flat mirrors (18), (19) optically coupled to the outputs of the first optical unit (2), one of which is made in the form of a beam splitter (18 ), and a telescopic sighting system (20), containing a lens (21) sequentially located on the same optical axis, a reticle with a sighting mark (22) and an eyepiece (23) optically connected to the first output of the first optical unit (2) using a beam splitter ( 18) and with the second output of the first optical block and (2) via a beam splitter (18) and a second plane mirror (19) of the second optical unit (3). Moreover, the second optical unit (3) is installed with the possibility of its output from the radiation beam of the mirror collimator (1), which passed the first optical unit (2) and is equipped with a second optical compensator made in the form of two wedge-shaped plates (24), (25), each of which is installed along the radiation of the first and second outputs of the first optical unit (2).

Description

The utility model relates to the field of instrumentation, and more specifically to devices for controlling the imbalance of the visual and thermal imaging channels of combined sights.

A device is known for monitoring the imbalance of the thermal imaging and visual channels of combined sights [1], consisting of optically coupled mirror collimator and optical unit for pairing the mirror collimator with visual and thermal imaging channels of the combined sight. The mirror collimator contains a source of visible and infrared radiation, a grid and a mirror lens. The optical unit is installed at the output of the mirror collimator and is made in the form of two parallel channels. At the same time, at the output of the first channel of the optical unit that is optically connected with the visual channel of the combined sight, an optical compensator for errors in the direction of light beams in the form of two rotating wedges is installed, and at the output of the second channel, optically connected with the thermal imaging channel of the combined sight, there is a protective glass that transmits thermal radiation.

The disadvantage of this device is the impossibility of checking the parallelism of the channels of the optical unit, which provides the pairing of the mirror collimator with the visual and thermal imaging channels of the combined sight, during the operation of the device in laboratory and field conditions, which is necessary to improve the accuracy of the control of the parallelism of the visual and thermal imaging channels of the combined sight.

The objective of the utility model is to increase the accuracy of controlling the imbalance of the visual and thermal imaging channels of a combined sight by providing the ability to conduct operational monitoring of the imbalance of the channels of the optical unit of the device during operation in laboratory and field conditions.

The problem is solved in that in a device for controlling the imbalance of the visual and thermal imaging channels of combined sights, containing optically coupled mirror collimator, including a source of visible and infrared radiation, a grid and a mirror lens, and the first optical unit for pairing the mirror collimator with visual and thermal imaging channels of the combined sight installed at the output of the mirror collimator, the first

and the second outputs of the first optical unit are optically connected respectively with the visual and thermal imaging channels of the combined sight, with the first optical compensator installed at the first output and a protective glass that transmits thermal radiation at the second output, the novelty is that the protective glass is installed with the possibility the output from the course of the radiation beam that has passed the second exit of the first optical unit, or is made of a material that partially transmits visible radiation, a second an optical unit comprising a system of two parallel rigidly connected flat mirrors optically coupled to the outputs of the first optical unit, one of which is made in the form of a beam splitter, and a telescopic sighting system containing a lens sequentially located on the same optical axis, a reticulated grid and an eyepiece optically coupled to the first output of the first optical unit using a beam splitter and to the second output of the first optical unit using a beam splitter and a second flat mirror of the second pticheskogo block. Moreover, the second optical unit is installed with the possibility of its output from the radiation beam of the mirror collimator that passed the first optical unit and is equipped with a second optical compensator made in the form of two wedge-shaped plates, each of which is installed along the radiation of the first and second outputs of the first optical unit.

The installation of a protective glass with the possibility of its removal from the course of the radiation beam passing through the second channel of the first optical unit, or its implementation from a material partially transmitting visible radiation, as well as the introduction of a second optical unit made in the form of two rigidly connected to each other and mutually parallel flat mirrors and a telescopic sighting system, and installed with the possibility of its output from the beam of light beams of the mirror collimator, which passed the first optical unit, allows for operational control of the parallelism of the output channels of the first optical unit before each use of the device, both in laboratory and in the field, which improves the accuracy of monitoring the parallelism of the visual and thermal imaging channels of combined sights.

The essence of the utility model is illustrated in the drawing. The figure shows the optical functional diagram of the device.

A device for controlling the imbalance of the visual and thermal imaging channels of combined sights contains optically coupled mirror collimator 1, a first optical block 2 and a second optical block 3. The mirror collimator 1 includes a mirror lens 4, in the rear focal plane

which has a grid 5 with streaks that are transparent to visible and thermal radiation. The grid 5 is highlighted by a radiation source 6, which consists of a heating element 7 with a device for adjusting its temperature 8 and a source of visible radiation 9 with a device for adjusting its brightness 10. The source of visible radiation 9 is optically coupled to the heating element 7. The mirror 11 is made with a hole in its central parts. The image of the grid 5 through the hole in the mirror 11 is projected to "infinity". At the output of the mirror collimator, a first optical unit 2 is installed, made in the form of two parallel channels.

On the axis of the first channel I, which is optically connected with the visual channel of the combined sight, a beam splitter plate 12 is installed in series, which transmits part of the visible radiation and reflects the thermal radiation and part of the visible radiation, and the first optical compensator 13, in the form of two consecutive wedge-shaped plates 14 and 15, installed with the possibility of rotation around the optical axis of the first channel I of the first optical unit. In this case, the beam splitting plate 12 is installed at an angle of 45 ° to the optical axis of the mirror collimator 1.

On the axis of the second channel II, which is optically coupled to the thermal imaging channel of the combined sight, there are sequentially a flat mirror 16 mounted parallel to the beam splitter plate 12 and a protective glass 17 made of zinc selenide, which ensures transmission of both thermal radiation and visible radiation. The protective glass 17 can be made of a material that transmits only thermal radiation, for example, germanium, but in this case, it must be structurally possible to remove it from the path of the radiation beam passing through the second channel of the first optical unit 2.

At the output of the first optical unit 2, a second optical unit 3 is installed, including a system of two parallel rigidly connected flat mirrors 18, 19 and a telescopic sighting system 20. The mirror 18 is made in the form of a beam splitting plate transmitting visible radiation coming out of the first channel I of the first optical unit 2 and reflecting thermal and visible radiation emerging from the second channel II of the first optical unit 2 and reflected from the mirror 19. The telescopic sighting system 20 consists of optically coupled lens 21, a set and with the target plate 22 and the eyepiece 23.

The grid with the target mark 22 is optically coupled to the grid 5 of the mirror collimator 1. Functionally, it provides the alignment of the second optical unit 3 and

allows you to determine the amount of non-parallelism of the first I and second II channels of the first optical unit 2.

To compensate for errors in the direction of light beams, the second optical unit 3 is equipped with a second optical compensator made in the form of two wedge-shaped plates 24 and 25, each of which is installed along the radiation of the first and second outputs of the first optical unit, which function as protective glasses of the second optical unit 3.

The device operates as follows.

The beam of rays from the radiation source 6 of the mirror collimator 1, consisting of rays of visible and thermal radiation, illuminates the grid 5, then, passing through the hole in the mirror 11, falls on the reflective surface of the mirror lens 4, is reflected from it and falls on the mirror 11. Reflected from the mirror surface of the flat mirror 11, the beam of rays falls on the beam splitter plate 12. The grid 5 is located in the rear focal plane of the mirror lens 4, therefore, the rays after reflection from the mirror lens fall on the flat mirror 11 and reflect extend from it in a parallel beam. Part of the beam of visible radiation passes through the beam splitter plate 12, the first optical compensator 13, enters the second optical block 3 and, passing through the wedge-shaped plate 24 and the beam splitter plate 18, falls on the lens 21 of the telescopic sighting system 20.

The beam of thermal radiation rays and the second part of the visible radiation are reflected from the beam splitter plate 12, then from the planar mirror 16, passes through the protective glass 17 and fall on the lens 21 of the telescopic sighting system 20, passing through the wedge-shaped plate 25 and reflected from the system of plane mirrors 19 and 18 .

The telescopic sighting system 20 of the second optical unit 3 forms in the plane of the grid with the sighting mark 22 images of the grid of the mirror collimator 5, which are examined by the operator in the eyepiece 23 simultaneously with the sighting mark of the grid 22 of the telescopic sighting system 20.

Since the output channels of the first optical unit 2 are optically matched with the input channels of the second optical unit 3, then, with the channels of these optical units being strictly parallel, the operator, through the eyepiece 23 of the telescopic sighting system 20, examines the images of the grid 5 of the mirror collimator 1 formed by the first 2 and second 3 optical units combined with the target mark of the grid 22 of the telescopic target system 20.

The displacement of the image of the grid 5 of the mirror collimator 1 relative to the brand of the grid 22 of the telescopic sighting system 20 indicates the presence of non-parallelism I

and II channels of the first optical unit, for the elimination of which the first optical compensator 13 is used.

The inventive device is compact. It does not require a significant investment of time for the preparation and conduct of the control, since the preparation for the control consists only in installing a second optical unit in front of the output channels of the first optical unit, and the control process only in observing the telescopic sighting system in the eyepiece. The accuracy of monitoring the imbalance of the visual and thermal imaging channels of the first optical unit does not exceed 10 arc seconds.

Thus, a device for controlling the imbalance of the visual and thermal imaging channels of combined sights provides high accuracy control of the imbalance of the visual and thermal imaging channels of combined sights and allows you to quickly carry out monitoring, both in laboratory and in the field.

Sources of information used:

RB patent No. 1716 U, G01В 11/26, 2004 (prototype).

Claims (2)

1. A device for controlling the imbalance of the visual and thermal imaging channels of combined sights, containing optically coupled mirror collimator, including a source of visible and infrared radiation, a grid and a mirror lens, and the first optical unit for interfacing the mirror collimator with visual and thermal imaging channels of the combined sight, installed at the output of the mirror the collimator, the first and second outputs of the first optical unit are optically connected respectively with visual and thermal imaging the combined sight, and the first output has a first optical compensator, and the second output has a protective glass that transmits thermal radiation, characterized in that the protective glass is installed with the possibility of its output from the path of the radiation beam passing through the second output of the first optical unit, or from a material that partially transmits visible radiation, while a second optical unit is introduced into the device, including a system of two parallel rigidly coupled flat mirrors, optically coupled to the outputs of the first optical unit, one of which is made in the form of a beam splitter, and a telescopic sighting system containing a lens sequentially located on the same optical axis, a reticle with a reticle and an eyepiece optically connected to the first output of the first optical unit using a beam splitter and the second the output of the first optical unit using a beam splitter and a second flat mirror of the second optical unit, and the second optical unit is installed with the possibility of its output from the beam teachings of a mirror collimator that passed the first optical unit. 2. The device according to claim 1, characterized in that the second optical unit is equipped with a second optical compensator made in the form of two wedge-shaped plates, each of which is installed along the radiation of the first and second outputs of the first optical unit.