RU98597U1 - STAND FOR ADJUSTING THE OPTICAL-MECHANICAL INSTRUMENT - Google Patents

Abstract

 1. A bench for aligning an optical-mechanical device, comprising a frame with base surfaces for installing the device to be adjusted and an optical reading device, characterized in that an optical theodolite and a target mark are used as an optical reading device. ! 2. The stand according to claim 1, characterized in that the sighting tube of the optical theodolite is equipped with one or more lens nozzles.

Description

The invention relates to the field of alignment of an optical-mechanical device (hereinafter referred to as the device) used in navigation, including aviation, aiming, etc., for outputting information to the windshield, namely to the exact exhibition of the center of sight relative to the surfaces of the device, mating with the base surfaces of the frame of the object of operation.

Widely known are optical-mechanical devices for aiming, in which the sign-graphic information is displayed on the windshield of, for example, an aircraft (see patent No. EP 0157958, G02B 27/01; G09G 1/28; publ. 1985-10-16) .

A known stand for checking the accuracy of an aircraft sight used in the method according to the application of the Russian Federation No. 2006143795 F41G 3/32, publ. 06/06/20). It contains the attachment points of the device being adjusted, a reading device in the form of a wide-angle collimator, which forms a control grid with divisions by means of the optical sight scale, the vertical axis of which is perpendicular to the base of the sight, and its divisions correspond to divisions of the radar scale. In this case, the control of the perpendicularity of the vertical axis to the base of the device being adjusted is carried out visually by means of a control grid. This stand has several disadvantages. High accuracy of instrument alignment during serial production is not ensured. the accuracy of the instrument display depends on the visual perception of a particular tuner. At the same time, the width of the images of the control grid of the optical sight also affects the accuracy of the adjustment.

The technical result of the proposed alignment bench is to increase the accuracy of alignment of the device, which is dictated by the stringent operational requirements for an optical device in the aviation industry through the use of high-precision optical theodolite.

The technical result is achieved by the fact that in the test bench for alignment of optomechanical devices, containing a frame with base surfaces for installing the device to be aligned and an optical reading device, an optical theodolite with a target mark is used as the latter. Moreover, the theodolite sighting tube can be equipped with a standard or standard and additional (s) lens nozzles.

The essence of the technical solution is illustrated by drawings.

Figure 1 - stand with adjustable device.

Figure 2 - image of the imposition of the target mark of theodolite on the center of the instrument.

Figure 3 - stand with the target mark of the standard.

Figure 4 - image of the imposition of the target mark of theodolite on the center of the target of the target mark.

In Fig. 1, the alignment stand includes a frame 1, the reference point 2 of which is located in the plane of symmetry of the stand, while frame 1 is identical to the frame installed on the object of operation (for example, an aircraft), and has base surfaces for installation of the alignment device 3. On on the same axis as device 3 is an optical theodolite 4 (hereinafter referred to as theodolite) with a lens nozzle 5, horizontally aligned and set to a predetermined height of sight N. Figure 2 shows the superposition of the target mark 6 of theodolite 4 on the sight center 7 of device 3. On Phi g. 3, the target mark of reference 8 is mounted on the base surfaces of the frame 1, while the target tube of theodolite 4 is directed to the center 9 of the intersection of the marks of the target mark of reference 8 (Figure 4).

The device operates as follows.

Adjustable device 3 is installed on the base surfaces of the frame 1, determining the position of the device relative to the reference point 2. By turning the frame 1 of the device 3 relative to the reference point 2 of the frame 1, its base plane is brought into a horizontal position. Next, the longitudinal plane of symmetry of the frame 1 of the device 3 is combined with the line of sight of the theodolite 4 in one vertical plane. The reading of the angle of the horizontal circle of the theodolite is zeroed, i.e. an exhibition of the zero position of the line of sight of the theodolite 4 is made. Theodolite 4 is calibrated in accordance with the instructions for use attached to it. The sighting axis of the theodolite pipe 4 is set at the sighting height H to the center 9 of the intersection of the marks of the sighting mark of standard 8 installed in the focal plane of instrument 3. This allows you to get the specified sighting height of instrument 3, the same for all instruments of each series.

Next, the target mark 8 of the standard is removed from the stand, while the frame 1 and theodolite 4 remain in the exposed position. After that, an adjustable device 3 is installed on the stand and the center of the sighting device of the device 3 is combined using its controls (for example, quotation screws), with the target mark 6 of theodolite 4

Due to the fact that, as a rule, theodolite is designed to work at considerable distances, to reduce it, a standard lens nozzle 5 on the theodolite 4 sighting tube (supplied in the singular with most theodolites) was used, which allows to reduce the working distance for tuning by target mark standard to 1 meter. One of the distinguishing features of the proposed stand is the use of an additional nozzle (additional nozzles) on the theodolite sighting tube, which is identical to the standard one, but is not supplied with the theodolite. This allows you to reduce the working distance of the theodolite to 0.5 meters, which allows you to use the stand for the alignment of devices with a focal length of 0.5 meters.

Compared with the prototype, the width of the grid of theodolite telescope filaments is much smaller than the visually perceived width of the wide-angle collimator patterns. Thus, the width of the grid of threads has an extremely small effect on the error of measurements.

Tests have confirmed the high performance of the stand, providing high accuracy characteristics of aligned devices and achieving the claimed technical result and guaranteed high interchangeability of products.

Claims (2)

1. A bench for aligning an optical-mechanical device, comprising a frame with base surfaces for installing the device to be adjusted and an optical reading device, characterized in that an optical theodolite and a target mark are used as an optical reading device. 2. The stand according to claim 1, characterized in that the sighting tube of the optical theodolite is equipped with one or more lens nozzles.