"CRYO F-PHP" Automated Cryogenic Installation for Certifying the Characteristics of Optical Filters and Photodetectors

Authors

  • A.G. Demishev Galkin Physical-Technical Institute of the NAS of Ukraine

DOI:

https://doi.org/10.15407/scine15.02.005

Keywords:

certification of the parameters of optical filters and photodetectors, cryogenic optical installation

Abstract

Introduction. Defense technology industries rapidly growing, the problem of certification of optical filters and photodetectors becomes very relevant.
Problem Statement. Certification of the characteristics of optical filters and photodetectors at the metrological level is complicated by the fact that measurement results obtained in a series of consecutive experiments are practically incomparable.
Purpose. An ideal solution of the whole complex of problems is to create an automated cryogenic installation for certifying the characteristics of optical filters and photodetectors within the temperature range from 2.5 to 300 K, in single experiment.
Materials and Methods. The material of this research is a design of the cryogenic part of the installation. Its efficiency is determined by analyzing the thermal balance modules and by the method of certification of filters and photodetectors in single experiment.
Results. CRYO F-PHP installation has been proposed, its cryogenic part consists of a functionally completed fully rotating cassette module with a holder of photoelectric sensors and a module with fully rotating cassette with filters. Each module has shields and is equipped with its own system for cooling and maintaining the desired temperature, as well as with current collectors and identifiers of the number of photodetector and filter in the operating position.
Conclusions. The installation design and the corresponding research methodology provide a solution to the whole complex of problems related to certifying the parameters of optical filters and photodetectors in the temperature range from 2.5 to 300K, at the metrological level, in single experiment and simulating their real operation in normal conditions. Due to advantages of the design and efficiency of certification in a single experiment, the proposed installation significantly surpasses the known analogs.

References

Handbook of physico-technical fundamentals of cryogenics. (1985). Moscow: Energoatomizdat.

Kaganer, M. G. (1979). Heat and mass transfer in low-temperature structures. Moscow: Energiya, 1979.

Demichev, A. G. (1980). Investigation of heat transfer in the neck, method of calculation and development of cryostats and cryogenic systems. PhD (Techn.). Kharkov [in Russian].

Galkin, A. A., Kurochkin, V. I., Demeshev, A. G., Suplin, V. Z., Pelich, D. P. (1982). Study of heat transfer and the creation of cryostats with long service life. Doklady AN USSR. Series A-Physical, mathematical and technical Sciences, 8, 55–58.

A. s. USSR №436334, MKI G05d 23/30, G05d 16/06. Temperature-controlled cryostat device. V. S. Medvedev, V. M. Ermakov, P. V. Vodolazsky, V. B. Podolich, A. G. Gohmul, V. H. Gohman, A. F. Prokopiuk. Declared 03.12.1970, publ. 15.07.1974, bull. No. 26.

Zharkov, I. P., Vashenko, O. M., Pogrebnjak, S. V., Safronov, V. V. (2010). Optimizer reguluvannya temperature have liquid- running cryostats. UFJ, 55(3), 351–356.

Demichev, A. G., Unesichin, N. E., Suplin, V. Z., Pishvanova, N. A., Hurtjak, A. A., Ponomarenko, A. N., Borodina N. N. (1982). Helium cryostats single series "KG". PTE, 4, 244.

Demichev, A. G., Hurtjak, A. A. (1991). Nitrogen cryostats for photodetectors. Opto-mechanical industry, 6, 45–48.

Demichev, A. G., Suplin, V. Z., Naymushin, A. E., Hurtiak, A. A., Silchenko, V. A., Pelich, N. I. (1981). The cryogenic system with adjustable temperature studies inelastic neutron scattering in a magnetic field. Questions of atomic science and technology, Series - General and nuclear physics, 3(17), 72–74.

Belyaeva, L. I., Silaev, V. I., Stetsenko, Yu. E. (1987). Runing cryostats for laboratory studies. Kiev: Naukova dumka.

Demichev, A. G., Pelih, D. P., Ratmansky, D. S., Borodina, N. N., Zolotuhin, A. A. (1980). Continuous flow Cryostat for optical and laser research. PTE, 5, 258.

Zikeev, P. E., Demishev, A. G. (1982). Restoration of values of metrological characteristics of cryostats from empirical data. Collection “III All-Union meeting on thermophysical measurements and their metrological support” (Moscow, 1982). P. 14-16.

Demishev, A. G., Suplin, V. Z., Borodina, N. N., Shirkov, A. K., Dubinsky, S. I. (1984). Mathematical modeling and experimental study of the temperature change dynamics of cryogenic systems. Collection “All-Union scientific conference “Temperature-84” - status and prospects of development of temperature measuring means by contact and non-contact methods” (Lviv, 1984). Volume 1. P. 247.

Zikeev, P. E., Demichev, A. G. (1985). Determination and optimization of the dynamic characteristics of the cryostat systems. Standardization and Metrology. Materials of III All-Academic school on standardization and Metrology (Tbilisi, 1985). P. 193–200.

Savchenko, A. G., Shirkov, A. K. (1982). Liquid helium level Sensor. PTE, 2, 232.

Demichev, A. G., Pelich, N. I., Gaidukov, L. J., Proshkuratov, N. V., Kostianok, N. V., Petushkov, G. I. (1984). Device for measuring and regulating temperature on the basis of microcomputers. Collection “All-Union scientific conference “Temperature-84” - status and prospects of development of temperature measuring means by contact and non-contact methods” (Lviv, 1984). Volume 2. P. 146.

A. s. of the USSR, 885692 МКС5 F 17 C 7/02/ / F25 D 3 /10/. Cryostat. D. P. Pelich, A. G. Demichev, D. S. Ratmansky, V. S. Suplin. No. 2862633; stated 03.01.80, publ. 30.11.81, bull. No. 44.

A. s. of the USSR, 1286870 МКС5 F 17 C 13/087/ / F25 D 3 /10/. Cryostat. A. G. Demichev, D. P. Pelih, V. S. Suplin. No. 3888284; stated 24.04.85, publ. 30.01.87, bull. No. 4.

Demichev, A. G., Pelich, D. P., Shirkov, A. K., Vorobev, V. G., Suplin, V. S., Zikeev, P. E., Dubinsky, S. I., Jusko, T. T. (1988). Automated Cryogenic installation for spectrophotometric studies. Optical-mechanical industry, 3, 26–29.

Demichev, A. G., Pelih, D. P., Shirkov, A. K., Uksusova, S. A., Dubinsky, S. I. (1992). Compact cryostats with variable temperature for optical studies. Optical journal, 3, 64–68.

A. s. of the USSR, 1778641 МКС5 G 01 N 21/55. Device for low-temperature measurements of optical characteristics of the samples. A. G. Demichev, V. G. Vorobev, D. P. Pelih, A. K. Shirkov. No. 4854050; stated 24.06.90, publ. 30.11.92, bull. No. 44.

Patent of Ukraine No. 84158 IPC (2013 01 ) F25B 29/00. Damishev A. G. CRYOSTAT CRYO – FILTER - PHOTOREGISTER.

Patent of Ukraine No. 104700 IPC-12 F 25 B 29/00. Damishev A. G. Cryococomplex for assessment of optical filters and photortgisters.

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Published

2024-09-04

How to Cite

Demishev, A. (2024). "CRYO F-PHP" Automated Cryogenic Installation for Certifying the Characteristics of Optical Filters and Photodetectors. Science and Innovation, 15(2), 5–14. https://doi.org/10.15407/scine15.02.005

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Scientific Basis of Innovation Activities