For citation:
Fateev S. A., Putsylov I. A., Smirnov S. E. Glass Carent Lead of Lithium-Fluorocarbon Power Source. Electrochemical Energetics, 2019, vol. 19, iss. 1, pp. 37-?. DOI: 10.18500/1608-4039-2019-19-1-37-47, EDN: WOTMZK
Glass Carent Lead of Lithium-Fluorocarbon Power Source
The influence of lithium-fluorocarbon glass leads on the stability and preservation, as well as the behavior of differentcurrent leads of insulator is studied. It is shown that the most resistant glass for lithium output is silicon-free glass C62. The behavior of the fluorocarbon cathode current lead (titanium, niobium, molybdenum-rhenium) during storage is investigated. Discovered high corrosion niobium current lead correlation between OCV element and the intensity of corrosion of niobium current lead.
1. Kedrenskii I. A., Dmitrenko V. E., Grudyanov I. I. Litievye istochniki toka [Lithium power sources]. Moscow, Energoatomizdat Publ., 1992. 240 p. (in Russian).
2. Himicheskie istochniki toka : spravochnik / pod red. N. V. Korovina, A. M. Skundina [Chemical power sources. Ed. by N. V. Korovin, А. M. Skundin]. Moscow, MPEI Publ., 2003. 740 p. (in Russian).
3. Nizhnikovskii E. A. Sovremennye elektrohimicheskie istochniki toka [Modern electrochemical sources of electric current]. Moscow, Radiotehnika Publ., 2015. 296 p. (in Russian).
4. Kedrinskii I. A., Yakovlev V. G. Li-ionnye akkumuliatory [Li-ion batteries]. Krasnoyarsk, IPK Platina Publ., 2002. 268 p. (in Russian).
5. Skundin A. M., Efimov O. N., Yarmolenko O. V. Current state and development prospects of lithium accumulators. Uspehi himii [Аchievements of chemistry], 2002, vol. 71, no. 4, pp. 378–398 (in Russian).
6. Fateev S. A. Istochnik toka dlya implantiruemych meditsinskich priborov [Power source for implanted medical devices]. Patent RF, no. 33000, 2003. Available at: https://yandex.ru/patents/doc/RU33000U1_20031010 (accessed 15 January 2019) (in Russian).
7. Fateev S. A. Modern power sources for cardioelectronics. Eletrochemical Energetics, 2011, vol. 11, no. 4, pp. 223–228 (in Russian).
8. Shal’dah M. Elektrokardioterapiya [Electrocardiotherapy]. Saint Petersburg : Severo-Zapad Publ., 1992. 256 p. (in Russian).
9. Istephanous N. S., Fester K., Merrit D. R. Glass seal corrosion in liguid lithium electrolyte batteries. J. Electrochem. Soc., 1984, vol. 131, no. 8, pp. 293.
10. Bunker B. C., Douglas B. C., Quinn R. K. Glass corrosion in ambient temperature lithium battery headers. J. Mater Res., 1987, vol. 2, no. 2, pp. 182–194.
11. Bunker B. C., Leedecke C. J., Levy S. C., Grafts C. C. Glass-to-metal seal corrosion in lithium-sulfur dioxide cells. Proc. 8th Power Sources Symposium. Ed. by J. Thomson. New York, Academic, 1981, pp. 5361.
12. OST 11 027.010-75. Steklo elektrovakuumnoe. Marki [Electron-tube glass. Brands]. Saint Petersburg, RNII “Elektrostandart”, 1975. 9 p. (in Russian).
13. OST 16 0.800.356-80. Steklo dlya elektrotehnicheskih istochnikov sveta. Marki, tehnicheskie trebovaniya I metody ispytaniya [Glass for electrotechnical light sources. Brands, technical requirements and test methods]. Saransk, VNII istochnikov sveta imeni A. N. Lodygina, 1980. 45 p. (in Russian).
14. Fateev S. A. Storageability of lithium – fluorocarbon power sources. Elektrokhimiya [Russian Journal of Electrochemistry], 2000, vol. 36, no. 7, pp. 878–883 (in Russian).
15. Ljubimov M. L. Spai metalla so steklom [Glass-to-metal seal]. Moscow, Leningrad, Gos. Energeticheskoe izdatel’stvo, 1967. 360 p. (in Russian).
16. Kazarnovskii D. M., Yamanov S. A. Radiotehnicheskie materialy [Radio engineering materials]. Moscow, Vysshaja shkola Publ., 1972. 125 p. (in Russian).
17. Fateev S. A., Ismmatov K. Yu., Lutfullaev Sh. H., Rutchin I. G., Schuvalova K. M., Batrakov Y. A., Tumanov B. I. Elektroizoljacionnaya kompoziciya [Electrical insulation composition]. Avtorskoe svidetel’stvo RF [Certificate of authorship RF], no. 182926, 1992 (in Russian).
18. Alashkin V. M., Batrakov Ju. A., Kukushkin A. N., Nikolenko P. I., Romadin V. F., Tumanov B. I. Experience of a research, development and tests of power supplies based on lithium the chemical sources of electric current for the missile and space equipment. Fundamental’nye problem preobrazovanija energii v litievyh elektrohimicheskih sistemah : Materialy X Mezhdunar. konf. [Fundamental problems of energy conversion in lithium electrochemical systems : materials X International Conference]. Pod red. I. A. Kazarinova. Saratov, Izd-vo Sarat. un-ta, 2008, pp. 3 (in Russian).
19. Fateev S. A., Pucylov I. A., Smirnov S. E., Fomin D. V. Lithium-fluorocarbon power source for gastroscopy. Eletrochemical Energetics, 2017, vol. 17, no. 3, pp. 135–142 (in Russian). DOI: https://doi.org/10.18500/10.18500/1608-4039-2017-3-135-142
20. Fateev S. A. Development trends of chemical sources of electric current for medical devices. Vestnik MEI [Bulletin of MPEI], 2018, no. 2, pp. 102–113 (in Russian).
21. Weiss D., Taylor W., Miller J., Lessar J., Kraska R. Battery with weldable feedthrough. Patent US, no. 5306581, 1994. Available at: https://patents.justia.com/patent/5306581 (accessed 15 January 2019).
22. Sunderland W. C., Haas D. P. Feedthrough pin insulator, assembly and method for electrochemical cell. Patent US, no. 5811206, 1998. Available at: http://www.freepatentsonline.com/5811206.html (accessed 15 January 2019).
23. Fateev S. A., Tuseeva E. K., Skundin A. M. Corrosion of current taps and diagnostic problems of fluorocarbon and lithium elements. Eletrochemical Energetics, 2010, vol. 10, no. 4, pp. 182–186 (in Russian).