Multilayer nested conical surface type X-ray grazing incidence optical lens

Abstract

The invention brings forward a multilayer nested conical surface type X-ray grazing incidence optical lens. The multilayer nested conical surface type X-ray grazing incidence optical lens comprises a lens barrel (1), a front heat shield assembly (2), a rear heat shield assembly (3), a front collimation assembly, a heat insulation pad (6), a front web (7), an eyeglass layer (8), a support rod (9) and a rear web (10). The eyeglass layer (8) is nested on the support rod (9), the lens barrel (1) is sleeved at the outer side of the eyeglass layer (8), one end of the lens barrel (1), one end of the eyeglass layer (8) and one end of the support rod (9) are fixedly connected with the front web (7), and the other ends are fixedly connected with the rear web (10). The front collimation assembly is installed between the front web (7) and the front heat shield assembly (2); and the rear heat shield assembly (3) is installed on the rear web (10). According to the invention, reflection is carried out by use of multilayer eyeglasses, large-area collection of soft X-ray photons is realized, and the multilayer nested conical surface type X-ray grazing incidence optical lens has the advantages of simple structure, large effective area, stray light interference prevention, high environment adaptability, simple processing, installation and adjustment, and the like.

Description

technical field [0001] The invention belongs to the technical field of space optics and relates to a grazing incidence optical lens. Background technique [0002] X-ray pulsar navigation is suitable for fully autonomous navigation of spacecraft in near-Earth space, deep space exploration, and interstellar flight. It can provide comprehensive navigation information such as position, velocity, attitude, and time for most space mission spacecraft, and realize the navigation of spacecraft. Completely autonomous navigation has the advantages of strong reliability, good stability, high accuracy, and wide applicability. It is a new type of autonomous navigation technology with great development potential. It is an excellent choice for improving the performance of spacecraft autonomous navigation systems. Extremely important engineering practical value and strategic research significance. [0003] The measurement accuracy of X-ray pulse arrival time determines the accuracy of X-ray...

AI Technical Summary

Problems solved by technology

[0004] The existing soft X-ray grazing incidence optical lens mostly adopts Wolter-I structure, which focuses the soft X-ray on the focal plane through the double reflection of the parabolic primary mirror and the hyperbolic secondary mirror. This structure is mainly suitable for soft X-ray targets source imaging, but the parabolic primary mirror and the hyperbolic secondary mirror have complex shapes and are difficult to process. The two reflections reduce the total reflectivity of the optical lens. There is a strict coupling relationship between the parabolic primary mirror and the hyperbolic secondary mirror. Accurate alignment can achieve the focus of soft X-rays, and the installation and adjustment are difficult

[0005] Another commonly used soft X-ray grazing incidence optical lens is a lobster eye structure. This optical lens works on the principle of lobster eye imaging and can achieve large field of view observation (tens to thousands of square degrees), but its large field of view The field will introduce more background noise, and the instantaneous effective area is small, which reduces the signal-to-noise ratio, and is only suitable for X-ray sky survey observation and monitoring

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