RU202136U1 - CONSTRUCTION OF A TWO-CHANNEL SPECTRORADIOMETER FOR MEASURING THE RADIATION FORCE OF A ROCKET TORCH - Google Patents

Abstract

The utility model relates to the field of optoelectronic instrumentation and can be used in the construction of devices for measuring the integral radiation force of the torch of the propulsion system of the test object. axes, the first and second positive menisci located on both sides of the spectrum splitter, the first and second photodetectors. The first photodetector is cooled. The device provides simultaneous measurement of radiation intensity in two spectral ranges: 0.3-1.0 microns, and 1.0-2.5 microns. The technical results are a reduction in size and weight, as well as a simplification of the design. 1 wp f-ly, 1 dwg

Description

The utility model relates to the field of optoelectronic instrumentation and can be used in the construction of instruments for measuring the integral radiation force of the torch of the propulsion system of the test object.

Known spectroradiometer [RU 2125250, IPC G01J 3/28, published 20.01.1999], containing an entrance window, a housing in which a spherical mirror, a flat mirror, a modulator, a light filter, a photodetector, a control and data processing unit are located.

The features of the analogue coincide with the following features of the proposed utility model: entrance window, housing, spherical mirror, photodetector, control and data processing unit.

The disadvantages of the known analog include large dimensions and weight, as well as the complexity of the design.

Also known is a multichannel spectrometer [RU 2375686, IPC G01J 3/00, published on 10.12.2009], containing an entrance window, a housing that houses an entrance spherical mirror, a photo detector, a diffraction grating, an output spherical mirror, a movable platform, a multi-element photodetector, a block management and data processing.

The features of the analog coincide with the following features of the proposed utility model: entrance window, housing, spherical mirror, photodetector, control and data processing unit.

The disadvantages of the analogue include the complexity of the design and large weight and size characteristics.

The problem to be solved by the proposed utility model is to simplify the design, as well as to reduce the dimensions and weight of the device.

The technical results achieved when solving the problem are to simplify the design, as well as to reduce the size and weight of the device

Technical results are achieved due to the fact that a spectro-splitter installed in front of the rear focus of the spherical mirror perpendicular to the optical axis can be introduced into a two-channel spectroradiometer containing an entrance window, a housing in which a spherical mirror, the first and second photodetectors, and an electronic control and data processing unit are located ... Also, the first and second positive menisci can be introduced, located on either side of the spectrum splitter. In addition, the first photodetector can be cooled.

The essence of the proposed utility model is illustrated by a graphical image, which shows the optical scheme of the device.

The drawing shows an example of a specific implementation of a two-channel spectroradiometer.

The spectroradiometer contains the following elements: a single housing 1 with a protective entrance window 2, a spherical mirror 3. The spectral splitter 4 is installed perpendicular to the optical axis in front of the rear focus of the spherical mirror 3. On both sides of the spectral splitter 4, positive menisci 5 and 6 are installed, focusing radiation on the first 7 and the second 8 photodetectors.

The device works as follows. Radiation from a distant object passes through the protective entrance window 2 and falls on the spherical mirror 3. Reflected from the spherical mirror 3, the optical radiation falls on the spectral splitter 4. Optical radiation of the spectral range 0.3-1.0 μm is reflected from the spectral splitter 4 and is focused by the positive meniscus 6 on the photodetector 8. Optical radiation in the spectral range of 1.0-2.5 μm passes through the spectral splitter 4 and is focused by the positive meniscus 5 on the cooled photodetector 7.

Thus, a two-channel spectroradiometer can be realized.

The claimed two-channel spectroradiometer can significantly simplify the design, reduce the size and weight.

The device provides simultaneous measurement of radiation intensity in two spectral ranges: 0.3-1.0 μm, and 1.0-2.5 μm.

Claims (2)

1. A two-channel spectroradiometer containing an entrance window, a housing housing a spherical mirror, the first and second photodetectors, an electronic control and data processing unit, characterized in that a spectral splitter is introduced, installed in front of the rear focus of the spherical mirror perpendicular to the optical axis; introduced the first and second positive menisci, located on both sides of the spectrum splitter. 2. A device according to claim 1, characterized in that the first photodetector is cooled.

Images