Microwave gas-discharge sulfur vapor lamp
Main Article Content
Abstract
Systematization and analysis of data on microwave gas-discharge lamps and comparison of existing types of lighting devices with microwave gas-discharge plasma lamps were conducted. The feasibility of applying such types of lamps at certain conditions, their advantages and future prospects have been proved. Reasonable selection of sulfur vapor as a glowing plasma medium is made. The proposal for the choice of element base for building a microwave gas-discharge lamp is developed. The directions of further research and development in this field were determined.
References 10, figures 3, tables 2.
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References
Rokhlin, H. (2006). Enquiry volume in lighting engineering. Ed. by Aizenberg Yu. Moskva. Znak. P. 972 (Rus).
Plasma illuminating lamp: ecological compatibility and continuous spectrum. (2011). www.magazine-svet.ru/review/63804 (Rus).
Zhidkov, R. A, Malyshev, V. V. (2013). Plasma irradiator for growth of green planting in hothouse. Herald VIESH. Vol. 1(10), pp. 45-47 (Rus).
Alexandrova, O. Yu. Bondarenko, S. V. Gutsayt, E. M. Zhidkov, R. A. (2013). Plasma lighting devices based on microwave discharge. Technologies of information-oriented society. Vol. 9, pp. 9-11 (Rus).
Zhidkov, R. A. (2103). Irradiator with sulfur lamp for crop production. All-Russian scientific conference “Microwave electronics issues”. Moskva, pp. 65-67 (Rus).
Sulfur lamp. Promissory commencement and... not predictable future? 1 part. Some history and about structure of the lamp, www.russianelectronics.ru:808/leader-r/review/2195/doc/56392 (Rus).
Luminous flux of typical light sources, www.dpva.info/Guide/GuidePhysics/LightAndColor/LightFlowEfficiency (Rus).
Zhidkov, R. A. (2008). Chamber, immersed and antenna-irradiating germicide devices combined ac-tion microwave-ultraviolet radiation an ozone. High-voltage vacuum-plasma electronics. Collected pa-pers VEI. Moskva, pp. 216-220 (Rus).
Volpian, O. D. Kuzmichev, A. I. (2012). Negative wave refraction. Introduction into physics and tech-nology of electromagnetic materials. Kiev, Avers. P. 360 (Rus).
Microwave transistors, http://www.ru.nxp.com/parametrics/16142/#/p=1,s=0, f=c54c27:1800;3100--c74923:250;450--cb6e65. Дата обращения: 30.09.15
