RU208629U1 - Autocollimation telescope - Google Patents

Abstract

The utility model is designed for high-precision pointing at distant objects and points, as well as for autocollimation binding to reflectors of the "flat mirror" type or reflective prisms as part of gyroscopic azimuth determination devices. The autocollimating optical tube contains a lens, an internal hood, a focusing component and an autocollimating eyepiece, including a Monchenko block prism with a mirror grid of threads applied to the surface of the second prism, a symmetrical eyepiece, and an illumination channel consisting of an illumination source and a single-lens condenser. At the same time, a vertical bisector is added to the grid of threads of the autocollimating eyepiece. EFFECT: providing the possibility of using an autocollimating spotting scope as a device for high-precision guidance of gyroscopic azimuth determination devices, while maintaining the possibility of autocollimating binding. 3 ill.

Description

The utility model relates to telescopic optical guidance devices. The device is designed for high-precision pointing at distant objects and points, as well as for autocollimation binding to reflectors of the "flat mirror" type or reflective prisms as part of gyroscopic azimuth determination devices.

Known autocollimation spotting scope [RU 119456 U1 / IPC G01B 11/26 / Application No. 2012110444/28 // 03/19/2012 // Autocollimation spotting scope / Zaitsev M.V., Plaksitsky E.V., Tareev A.M.], consisting of a lens sequentially located on the sighting axis, a beam-splitting cube-prism, the first grid with a measuring scale installed in the focal plane of the lens, and an eyepiece, as well as a projection system that includes an illumination system, a second grid with a mark and an optical compensator for aligning the axes, located on an axis perpendicular to the sighting axis and intersecting with it in the center of the beam-splitting face of the cube-prism, and the brand of the second grid is installed in the focal plane of the lens, as well as a mirror located on the axis of the projection system, the reflecting surface of which is facing the cube-prism.

A disadvantage of the known device is the use of two grids mounted on the projection and sighting axes, which causes difficulties in assembling, aligning the grids and aligning the axes, is accompanied by a complication of the design, as well as the lack of a focusing component in the lens and, as a result, internal focusing of the telescope.

The closest technical solution is the spotting scope of autocollimating theodolites [Zakharov A.I. Geodetic instruments. Directory. M: Nedra, 1989.], consisting of a lens sequentially located on the sighting axis, a focusing component and an autocollimating eyepiece. The autocollimating eyepiece consists of a Monchenko block prism with a grid of filaments, a symmetrical eyepiece and an illumination channel consisting of an incandescent lamp and a spherical mirror.

A disadvantage of the well-known spotting scope autocollimation theodolites is the use of a grid of threads for autocollimation theodolites, which does not allow it to be used for high-precision guidance [GOST 10529-96 Theodolites. General specifications].

The purpose of the utility model is to enable the use of an autocollimation spotting scope as a device for high-precision guidance of gyroscopic azimuth-determining instruments, while maintaining the possibility of autocollimation binding.

This goal is achieved by changing the design of the autocollimation eyepiece, namely the use of a modified grid of threads, which allows you to simultaneously perform high-precision aiming at distant objects and retain the possibility of autocollimation binding.

Figure 1 shows the optical scheme of the autocollimation telescope. The autocollimation telescope contains a lens 1, an internal hood 2, a focusing component 3, an autocollimation eyepiece 4.

Figure 2 shows a diagram of the autocollimation eyepiece. The autocollimating eyepiece includes a Monchenko block prism 5 with a mirror grid of threads deposited on the surface of the second prism, a symmetrical eyepiece 6, and an illumination channel 7, consisting of an LED 8 and a single-lens condenser 9.

The Monchenko block prism and the symmetrical eyepiece are located on the sighting axis. The illumination channel together with the Monchenko block prism form the projection system of the autocollimation telescope, the axis of which intersects the line of sight in the center of the Monchenko block prism at an angle of 60°.

A five diaphragm hood located between the lens and the focusing component eliminates stray reflections from the interior surfaces of the telescope body.

An LED is used as a radiation source, with the ability to adjust the brightness of the radiation by changing the strength of the passing current. Uniform illumination of the grid of filaments is provided by a single-lens condenser made in the form of a lens designed for a minimum of spherical aberration.

The high accuracy of aiming the autocollimating telescope at point and distant objects is provided by a vertical bisector added to the grid of threads of the autocollimating eyepiece (figure 3).

Claims (1)

An autocollimating optical tube, consisting of a lens, a hood, a focusing component and an autocollimating eyepiece, including a Monchenko block prism with a mirror grid of threads applied to the surface of the second prism, a symmetrical eyepiece and an illumination channel, characterized in that a vertical bisector is added to the grid of autocollimating eyepiece threads.

Images