RU119472U1 - TELESCOPE NOZZLE - Google Patents

Abstract

1. An attachment to the telescope, containing a housing connected to the telescope, characterized in that it additionally has at least one light filter with a high transmission capacity in the ultraviolet range, an image intensifier and an observation device, and / or fixing the image. ! 2. An attachment to a telescope according to claim 1, characterized in that at least one light filter made of special glass with a high transmission capacity in the ultraviolet range additionally has the shape of a lens. ! 3. A telescope attachment according to claim 1, characterized in that the observation and / or image fixation device is made in the form of an eyepiece for direct observation with one eye of the user. ! 4. Attachment to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a binocular for direct observation with two eyes of the user. ! 5. Telescope attachment according to claim 1, characterized in that the observation and / or image capturing device is made in the form of a CCD matrix connected to a computer. ! 6. A telescope attachment according to claim 1, characterized in that the observation and / or image capturing device is made in the form of a CMOS matrix connected to a computer. ! 7. Attachment to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a camera connected to the attachment to the telescope.

Description

The utility model relates to optical systems with devices for converting or amplifying an image, in particular, to nozzles for a telescope, containing a housing connected to the telescope and can be used in amateur astronomy when observing the starry sky using direct observation with the eyes or using a computer or fixing with using a camera or computer.

Known nozzles for telescopes containing a housing connected to a telescope, described in the patent for invention of the Russian Federation No. 2415478, published 2011. In it, a camera is attached to the telescope using the nozzle housing, with the help of which photographs of sections of the starry sky are obtained. Its disadvantage is the low information content of obtaining photographs of sections of the starry sky, since photographing is performed only in the visible range of light. In addition, in the specified invention it is impossible to observe the starry sky directly with the eye in the invisible range, in particular in the ultraviolet range.

The prior art also knows a nozzle for a telescope, containing a housing connected to a telescope, described in patent for invention of the Russian Federation No. 2321899, published 2008. In it, a camera is attached to the telescope using the nozzle body, with which photographs of areas of the starry sky are obtained.

This device is taken as a prototype of the proposed utility model.

Its disadvantage is the low information content of obtaining photographs of sections of the starry sky, since photographing is performed only in the visible range of light. In addition, in the specified invention it is impossible to observe the starry sky directly with the eye in the invisible range, in particular in the ultraviolet range. Also, this nozzle cannot be used as an additional optical system.

Based on this original observation, the present utility model mainly aims to offer a nozzle to the telescope, which allows at least to smooth out one of the above disadvantages.

To achieve this goal, the nozzle to the telescope additionally has at least one optical filter with high bandwidth in the ultraviolet range, an electron-optical converter and a device for observing and / or fixing an image sequentially installed along the path of the optical rays.

Due to this, it becomes possible to provide greater information content, as well as the ability to observe and / or fix the starry sky with the naked eye in the invisible range, in particular in the ultraviolet range.

There is a variant of the utility model in which at least one light filter made of special glass with high throughput in the ultraviolet range is additionally in the form of a lens.

Thanks to this characteristic, it becomes possible to introduce an additional optical system for, for example, enlarging and focusing the observed or captured image.

There is also a variant of the utility model in which the device for observing and / or fixing the image is made in the form of an eyepiece for direct observation with one eye of the user.

Thanks to this characteristic, it becomes possible to observe the starry sky directly with the eye in the ultraviolet range.

In addition, there is a variant of the utility model in which the device for observing and / or fixing the image is made in the form of a binocular for direct observation with two eyes of the user.

Thanks to this characteristic, it becomes possible to observe the starry sky in the ultraviolet range simultaneously with two eyes.

There is also a variant of the utility model in which the device for monitoring and / or fixing the image is made in the form of a CCD matrix connected to a computer.

Thanks to this characteristic, it is possible to convert the light signal of the ultraviolet range into an electric signal for subsequent processing using a computer.

Additionally, there is a variant of the utility model in which the device for monitoring and / or fixing the image is made in the form of a CMOS matrix connected to a computer.

Thanks to this characteristic, it is possible to convert the light signal of the ultraviolet range into an electric signal for subsequent processing using a computer.

There is also a variant of the utility model in which the device for observing and / or fixing the image is made in the form of a camera attached to the nozzle to the telescope.

Thanks to this characteristic, it becomes possible to obtain photographs of the observed starry sky in the ultraviolet range.

The set of essential features of the proposed utility model is unknown from the prior art for devices of similar purpose, which allows us to conclude that the criterion of "novelty" for the utility model is met.

Other distinguishing features and advantages of the utility model clearly follow from the description below for illustration and not being restrictive, with reference to the accompanying drawings, in which:

- figure 1 schematically depicts a functional diagram of the nozzle to the telescope.

The nozzle to the telescope includes a housing 1 connected to the telescope, additionally has at least one optical filter 2 with high bandwidth in the ultraviolet range, an electron-optical converter 3 and an observation and / or image capturing device 4. sequentially installed along the optical rays. FIG. .1 the arrows show the path of light, while the side from where the light falls is facing the telescope (not shown in FIG. 1).

As a filter with high bandwidth in the ultraviolet range, quartz glass transparent in the ultraviolet and visible parts of the spectrum without absorption bands in the wavelength range of 250-400 nm can be used.

As an electron-optical converter (EOC), the Sapphire EOP can be used, which has an electron-optical system with image wrapping, an input window of magnesium fluoride, a microchannel plate, a yellow-green fluorescent screen on glass or on an optical fiber, and the tellurium photocathode cesium.

As an observation and / or fixation device, a standard eyepiece, binocular, film or digital camera can be used.

The utility model can be manufactured using the above elements and assemblies produced by domestic and foreign industry, and used for amateur astronomy, which meets the criterion of "industrial applicability" for the utility model.

The nozzle to the telescope works as follows.

The nozzle is rigidly connected to a telescope, which is designed in such a way that it does not absorb light in the ultraviolet range. The telescope is sent to the observed area of the starry sky. The luminous flux from the starry sky passes through the telescope and enters the nozzle to the telescope. Depending on the type of filter with a high transmission capacity in the ultraviolet range, the light flux can only receive light in the ultraviolet range or in the ultraviolet and visible ranges.

The image intensifier transforms an invisible image of the portion of the starry sky (in the ultraviolet range) into a visible one, which can be observed using an eyepiece or binocular, as well as recorded using a camera or CCD or KNOP matrix.

The preceding description of exemplary embodiments of the utility model provides illustration and description, but is not intended to be exhaustive or to limit the utility model to the described precise elements. Modifications and changes are possible in the light of the above description or can be obtained from the application of the utility model. Modifications also include the use of various options for additional elements. For example, it is obvious that when used as a device for monitoring and / or fixing an image - a camera, an additional mounting device in the form of an adapter, a ring and other things, possibly equipped with an additional lens, may be required.

In accordance with the proposed utility model, a prototype nozzle for the telescope was made by the applicant.

As a filter with high bandwidth in the ultraviolet range, we used optical quartz glass KU-1, Alcor Technologies, which is transparent in the ultraviolet and visible parts of the spectrum without absorption bands in the wavelength range of 250-400 nm, with non-luminescent, radiation-optical sustainable.

As the image intensifier tube, the BASPIK Sapphire IC was used with the following characteristics:

Diameter of the working field of the photocathode 15 mm Spectral Sensitivity Range 120-360 nm

Length spectral sensitivity

waves λ = 250 nm not less than 20 mA / W Center Limit not less than 30 lines / mm

Spectral gain on

wavelength λ = 265 nm not less than 106 lm / W Dark background brightness no more than 1 × 10-5 cd / m2

Electron optical zoom in

center 1 ± 0.05 Weight no more than 50 g

Direct observation with an eyepiece was used.

Tests of the prototype nozzle for the telescope showed the following characteristics:

- the ability to observe with the eye in the ultraviolet range of 250-400 nm;

- the ability to capture images using a camera or computer, which allows you to expand the functionality of amateur astronomy.

Claims (7)

1. The nozzle to the telescope, comprising a housing connected to the telescope, characterized in that it additionally has at least one optical filter with high bandwidth in the ultraviolet range, an electron-optical converter and a monitoring device and / or image fixation. 2. The nozzle to the telescope according to claim 1, characterized in that at least one filter made of special glass with high throughput in the ultraviolet range additionally has the shape of a lens. 3. The nozzle to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of an eyepiece for direct observation with one eye of the user. 4. The nozzle to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a binocular for direct observation with two eyes of the user. 5. The nozzle to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a CCD matrix connected to a computer. 6. The nozzle to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a CMOS matrix connected to a computer. 7. The nozzle to the telescope according to claim 1, characterized in that the device for observing and / or fixing the image is made in the form of a camera attached to the nozzle to the telescope.