RU2275662C2 - Telescope - Google Patents

Abstract

FIELD: optical instrument engineering.

SUBSTANCE: telescope belongs to big astronomic telescopes with multi-element compound mirrors and can be used in astronomy for getting images of distant space objects and for monitoring of space from the point of view of asteroid safety. Telescope has case in form of hollow body of rotation with entrance window, image-forming device disposed inside the case, lodgment provided with section for the case which lodgment s mounted for azimuth turn, and guides disposed in alignment for turning case along horizontal axis. Case is made with two flat parallel cuts being orthogonal to axis of rotation of case around horizontal axis. Recess of lodgment is made in form of U-shaped slot in lateral cross-section to embrace case along its cuts. Guides for angular turn of case are mounted onto sides of U-shaped cut of lodgment turned to each other; guides are brought into contact with cuts of case.

EFFECT: improved reliability of big-sized telescope; high quality of image.

11 cl, 4 dwg

Description

The invention relates to optical instrumentation, namely, to designs of large astronomical telescopes with multi-element composite mirrors, and can be used in the field of astronomy to obtain images of remote space objects and monitor outer space from the point of view of asteroid safety.

A mirror telescope is known, comprising a fork suspension enclosed in a housing in which the telescope tube is movably mounted. An optical system is placed in the pipe (see Germany patent No. 3538208, G 02 B 23/02, 5/10, 1987).

A telescope with a main mirror with a diameter of 10 m is known, containing a composite segmented main mirror with a displacement drive, a control system, a secondary mirror, a telescope tube, an altazimuth mount (see A. Hewitt "Optical and infrared telescopes of the 90s", M .: Mir 1983, pp. 9-17).

An astronomical telescope is also known, comprising a housing spherical with an inlet, mounted on a fixed base with the possibility of azimuthal rotation, a telescope tube mounted in the housing using a fork slewing ring, an optical system coaxial to the inlet, including a primary and secondary mirrors placed in the tube telescope along the optical axis (see US patent No. 3791713, G 02 B 23/16, 1974).

The closest technical solution (prototype) to the proposed invention by design is a telescope comprising a body in the form of a hollow body of revolution with an input window, an image forming device located in the body cavity, a tool tray with a sample for the above body, mounted with the possibility of azimuthal rotation, and coaxially arranged guides for angular rotation of the housing (see patent RU 2082198, C1 6 G 02 B 23/00, 1997).

By the method of imaging an object and the device for its implementation, the closest technical solution is a telescope containing a 4-mirror optical system with a 25-meter composite main mirror for imaging an object, including adaptive forming optics with N mirror elements (see Grundmann Report on Options for Use of the Existing Pier with a New Telescope. INTERNET Website: http://www.cfht.hawaii.edu/ Reference).

The disadvantages of all of the above technical solutions are

- the complexity of the design, the increased moment of inertia of the movable part of the telescope, leading to the occurrence of transcendental loads on the optomechanical path and, as a result, reducing image quality;

- insufficient structural rigidity, contributing to the emergence of resonant vibrations leading to the displacement of optical elements and as a result to a deterioration in image quality;

- insufficient streamlining of the telescope structure, leading to an increase in wind loads, the occurrence of forced vibrations of the telescope structure from gusts of wind, to the emergence of additional turbulent flows near the input window, which also leads to a deterioration in image quality;

- insufficient stability of the alignment of the optical system of the telescope due to the strong dependence of the alignment errors on the relative spatial position of the elements of the optical scheme, which also leads to a deterioration in image quality.

The technical result from the use of the proposed technical solution is to simplify the design of the telescope, reduce the moment of inertia, increase the rigidity of the structure, eliminate or reduce the influence of distorting factors on image quality.

The specified technical result is achieved by the fact that in a telescope containing a body in the form of a hollow body of revolution with an input window, an image forming device placed in the body cavity, a tool tray with a sample for the above body mounted with the possibility of azimuthal rotation, and coaxially arranged guides for angular rotation of the housing, the housing is made with two flat parallel slices orthogonal to the axis of rotation of the housing, the lodgement sample is made in the form of a U-shaped slot in the cross section In order to cover the housing along its sections, the guides for angular rotation of the housing are mounted on the sides of the U-shaped lodgement facing each other and brought into contact with the housing sections.

In addition, the outer side surfaces of the lodgement and the housing are made paired and streamlined.

The guides for angular rotation of the housing are made of a closed annular shape and are placed in cylindrical grooves provided on the sides of the U-shaped lodgement sample facing each other.

Guides for angular rotation of the housing are placed in cylindrical grooves of the U-shaped pick of the tool tray with freedom of axial movement and are elastically drawn to the body sections.

The mechanism of preloading the guides for the angular rotation of the housing is made in the form of threaded elements with an axial cavity evenly spaced in the tool tray and spring-loaded pushers placed in the axial cavities of the threaded elements and interacting with their ends with the ends of the above-mentioned guides.

The outer side surface of the annular guides for angular rotation of the housing is made spherical with a radius of the sphere equal to half the diameter of the cylindrical grooves of the tool tray.

Recesses are provided on the surfaces of the body sections in the form of annular belts coaxial to the axis of rotation of the body, and fingers are installed in the tool tray, the ends of which are placed in the ring belts of the body sections.

At the ends of the fingers located in the annular belts of the sections of the housing, rolling bodies are mounted, interacting with the inner side surface of the above belts.

The fingers are mounted in a tool tray with a possibility of a turn, and the ends of the fingers with rolling bodies are mounted eccentrically relative to the axis of their turn.

The case is made of polymeric material, and its rubbing surfaces are reinforced with metal.

Between the guides for angular rotation of the housing and its side sections, liners of antifriction material are installed.

The specified technical result is also achieved by the fact that in the method of forming an image of an object based on the reception of a parallel light beam from the object with its subsequent focusing, before focusing the parallel light beam, it is uniformly compressed in the transverse direction.

And in the device for implementing the method of forming an image of an object containing adaptive forming optics, including N mirror elements, the forming optics is made in the form of sequentially installed and optically paired afocal and focusing systems.

In addition, the afocal system is made two-mirror, while its primary mirror is made in the form of a phase-correcting element.

The invention is illustrated by drawings, where in Fig.1 and Fig.2 shows a General view of the telescope in two projections, and in Fig.3 and Fig.4 - places I and II in Fig.2 on an enlarged scale.

The telescope consists of a housing 1 made with two flat parallel slices 2 orthogonal to the axis of rotation of the housing 1 in the form of a hollow body of revolution 3 with an input window 4, an image forming device located in the cavity of the housing 1, including adaptive forming optics, consisting of an afocal system in the form of a composite main mirror 5, which is a phase-correcting element, a secondary mirror 6 and a focusing system in the form of a combination of mirrors 7 and 8. Mirrors 6 and 7 are equipped with hoods 9. The main mirror 5 is installed in Ave 10, mounted on the stiffener 11 of the housing 1. In the focal plane of the forming optics mounted receiving and recording unit 12. A secondary mirror 6 is installed in the input window 4 by means of spiders 13 with the possibility of axial, transverse movement and rotation in two mutually perpendicular planes through the drive 14 The housing 1 is movably mounted on a lodgement 15 with an available sample 16 for the aforementioned housing 1. The lodgement 15 is mounted with the possibility of azimuthal rotation and is provided with coaxially arranged guides 17 for the angular rotation of the housing 1 relative to the lodgement 15 around the horizontal axis and relative to the fixed base 18 together with the lodgement 15 around the vertical axis. Unloading the movable part of the telescope is carried out, for example, by means of a magnetostatic suspension 19 of magnets fixed at the joints of the telescope-lodgement-base. The housing 1 is made with two parallel parallel slices 2 orthogonal to the axis of rotation of the housing, and the lodgement sample 16 is made in a U-shape in cross section to cover the housing along its slices 2, and the guides 17 for angular rotation of the housing 1 are mounted on the sides U facing each other -shaped sample 16 of the cradle and are brought into contact with the cuts 2 of the housing 1. The outer side surfaces of the cradle 15 and the housing 1 are made conjugated and streamlined in shape, for example, with installed pads 20.

To compensate for technological errors (tolerance for the deviation of parallelism between the surfaces of the slices 2 and to minimize the gap between the housing 1 and the cradle 15 in the horizontal direction), additional guides 21 of the clearance-free angular rotation of the housing 1 are installed, which are made of a closed annular shape and placed in cylindrical grooves 22 provided on facing each other sides of the U-shaped sample 16 of the cradle 15. The outer side surface of the guides 21 of a ring shape for angular rotation of the housing and 1 is made spherical with a radius of the sphere equal to half the diameter of the cylindrical grooves 22 of the cradle 15. In addition (see Fig. 3), the guides 21 are placed with freedom of axial movement and are elastically tightened to the sections of the housing 1 by a spring 23. The mechanism of preloading the guides 21 for angular the rotation of the housing 1 is made in the form of threaded elements 24 with an axial cavity 25 uniformly located in the lodgement 15 and spring-loaded pushers 26 located in the axial cavities of the threaded elements 24 and interacting with their ends with the ends of the above Awlavers. The axial movements of the threaded elements 24 are regulated by turning the head 35. On the surfaces of the slices 16 of the housing 1, recesses 27 are provided in the form of annular belts coaxial to the axis of rotation of the housing 1, and fingers 28 are installed in the tool tray 15, the ends of which are placed in the annular belts of the slices 16 of the housing 1. On the ends of the fingers 28 located in the annular bands 27 of the slices 16 of the housing 1, mounted rolling elements 29, interacting with the inner side surface of the above bands. The fingers 28 are mounted in the tool tray 15 with a possibility of a turn, and the ends of the fingers with rolling bodies are mounted eccentrically with respect to the axis of their rotation to tighten and eliminate backlash along the vertical axis. The preload is regulated by turning the head 30 and counter nut 31. The housing 1 can also be made (to facilitate construction) of a polymer material, and its friction surfaces are reinforced with metal. Between the guides 21 for angular rotation of the housing 1 and its side slices 16, liners 32 of antifriction material can be installed to reduce the amount of friction.

The proposed design of the telescope includes an imaging device, a servo drive system, a telescope control and position control system, including a guidance drive, as well as an adaptive control system for the composite main mirror, a telescope automatic balancing system, scientific-recording equipment, a wind protection system and protection against pavilion effects (not conventionally shown in graphic materials).

The telescope is oriented according to the given coordinates of the observed object. The control system drives the actuators 33 and 34 of azimuthal and angular turns. The optical axis of the telescope is directed to the observed object. The luminous flux from the object passes through the input window 4 of the housing 1 to the main mirror 5 and, being reflected successively from the mirrors 6, 7, 8 of the forming optics, forms an image of the observed object, in the plane of which the receiving and recording unit 12 is placed.

Consider imaging an object in a telescope using the optical system shown in figure 1, where item 5 is the composite main (primary) mirror of the telescope, item 6 is the secondary mirror, item 7 is the third mirror, item 8 is the fourth mirror .

The imaging in the telescope is as follows.

First, a parallel beam of light is received from the observed object, then it is uniformly compressed in the transverse direction, and only then it is focused. In this case, the beam is compressed by an afocal system (pos. 5-6), optically conjugated with a focusing system installed behind it (pos. 7-8). The afocal system is made of two-mirror (mirrors 5 and 6), and its primary mirror 5 is a phase-correcting element of the adaptive forming system.

To compensate for distortions of the radiation wavefront from the observed object in real time, an adaptive control system (not conventionally shown in graphic materials) is used by the spatial position of the elements (segments) of the composite main mirror 5, and an adaptive control system (also not shown) is used to correct the components of the telescope pointing error ) the spatial position of the secondary mirror 6 through the actuator 14.

From the above it follows that the proposed technical solution has the following advantages over the known.

1) The proposed design of the telescope allows us to simplify the design and improve image quality by eliminating distortion factors and a significant increase in the rigidity of the moving part of the telescope structure.

2) By reducing the weight of the movable part of the telescope, load characteristics have been improved to ensure reliable operation of the telescope with high image quality.

3) The environmental impact on the operation of the optical-mechanical path of the telescope is reduced due to the better streamlining of the telescope shape.

4) The quality of the formed image of the observed object is improved due to the increase in the efficiency of adaptive distortion correction due to the installation of a phase-correcting element in the entrance pupil of the telescope.

5) The life of the telescope has been increased by reducing the number of routine and preventive maintenance and increasing the stability of the characteristics of the telescope.

6) Improved ergonomics of the telescope and the conditions of its maintenance. Therefore, when using the proposed design gives a positive technical result - it improves the quality of the resulting image of the observed object.

Based on the application materials, the company has currently produced a prototype, tests of which have confirmed the achievement of the above technical result.

Claims (11)

1. The telescope, comprising a housing in the form of a hollow body of revolution with an input window, an image forming device placed in the cavity of the housing, a tool tray with a sample for the above housing, mounted with the possibility of azimuthal rotation, and coaxially arranged guides for angular rotation of the housing around the horizontal axis, characterized in that the casing in the form of a body of revolution is made with two flat parallel sections orthogonal to the axis of rotation of the casing around the horizontal axis, the lodgement sample is made in the form of U-shaped cuts in cross section to cover the body along its sections, and guides for angular rotation of the body around the horizontal axis are mounted on the sides of the U-shaped lodgement sample facing each other and brought into contact with the body sections. 2. The telescope according to claim 1, characterized in that the outer side surfaces of the lodgement and the housing are made paired and streamlined. 3. The telescope according to claim 1, characterized in that the guides for angular rotation of the housing around the horizontal axis are made of a closed annular shape and are placed in cylindrical grooves provided on the sides of the U-shaped lodgement sample facing each other. 4. The telescope according to claim 3, characterized in that the guides for angular rotation of the housing around the horizontal axis are placed in the cylindrical grooves of the U-shaped pick of the tool tray with freedom of axial movement and are elastically tightened to the sections of the housing. 5. The telescope according to claim 4, characterized in that the mechanism for preloading the guides for angular rotation of the housing around the horizontal axis is made in the form of threaded elements with an axial cavity evenly spaced in the lodgement and spring-loaded pushers placed in the axial cavities of the threaded elements and interacting with their ends with ends the above guides. 6. The telescope according to claim 3, characterized in that the outer lateral surface of the annular guides for angular rotation of the housing around the horizontal axis is made spherical with a radius of the sphere equal to half the diameter of the cylindrical grooves of the lodgement. 7. The telescope according to claim 1, characterized in that on the surfaces of the sections of the casing there are recesses in the form of annular belts coaxial with the axis of rotation of the body around the horizontal axis, and fingers are installed in the tool tray, the ends of which are placed in the ring belts of the sections of the casing. 8. The telescope according to claim 7, characterized in that at the ends of the fingers placed in the annular belts of the sections of the housing, rolling elements are mounted that interact with the inner side surface of the above-mentioned belts. 9. The telescope according to claim 8, characterized in that the fingers are mounted in a tool tray with a possibility of a turn, and the ends of the fingers with rolling bodies are mounted eccentrically relative to the axis of their turn. 10. The telescope according to claim 1, characterized in that the casing is made of polymeric material, and its rubbing surfaces are reinforced with metal. 11. The telescope according to claim 1, characterized in that between the guides for angular rotation of the housing around the horizontal axis and its side sections, liners of antifriction material are installed.

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