Using the Paratunsky geothermal field to provide heating for Kamchatka

封面

如何引用文章

全文:

开放存取 开放存取
受限制的访问 ##reader.subscriptionAccessGranted##
受限制的访问 订阅或者付费存取

详细

The Paratunsky geothermal field has been in operation since 1964, mostly in a self-flowing mode, with a discharge rate of approximately 250 kg/s of thermal water at temperatures of 70–90°С (47 Mw, with the waste water having a temperature of 35°С). The water drawn from the field is used for local heating, spa heating, and for greeneries in the villages of Paratunsky and Termal’nyi (3000 residents). The potential market of thermal energy in Kamchatka includes Petropavlovsk-Kamchatskii (180000 residents), Elizovo (39 000), and Vilyuchinsk (22 000). The heat consumption in the centralized heating systems for Petropavlovsk-Kamchatskii is 1 623 000 GCal per annum (216 Mw). A thermohydrodynamic model developed previously is used to show that the Paratunsky geothermal reservoir can be operated in a sustainable mode using submersible pumps at an extraction rate of as much as 1375 kg/s, causing a moderate decrease in pressure (by no more than 8 bars) and temperature (by no more than 4°С) in the reservoir. Additional geothermal sources of heat energy may include the Verkhne-Paratunsky and Mutnovsky geothermal fields.

全文:

受限制的访问

作者简介

A. Kiryukhin

Institute of Volcanology and Seismology, Far East Branch, Russian Academy of Sciences

编辑信件的主要联系方式.
Email: AVKiryukhin2@mail.ru
俄罗斯联邦, bul’var Piipa 9, Petropavlovsk-Kamchatskii, 683006 Russia

N. Zhuravlev

Institute of Volcanology and Seismology, Far East Branch, Russian Academy of Sciences

Email: AVKiryukhin2@mail.ru
俄罗斯联邦, bul’var Piipa 9, Petropavlovsk-Kamchatskii, 683006 Russia

参考

  1. Кирюхин А.В., Асаулова Н.П., Ворожейкина Л.А. и др. Условия формирования и моделирование эксплуатации Паратунского геотермального месторождения (Камчатка) // Геоэкология. Инженерная геология. Гидрогеология. Геокриология. 2017. № 3. С. 16–30.
  2. Федотов С.А., Сугробов В.М., Уткин И.С., Уткина Л.И. Возможности использования тепла магматического очага Авачинского вулкана и окружающих его пород для тепло- и электроснабжения // Вулканология и сейсмология. 2007. № 1. С. 32–46.
  3. Arnason B. Hydrothemal systems in Iceland traced by deuterium // Geothermics. 1976. V. 5. № 1/4. P. 71–81.
  4. Axelsson G., Gunnlaugsson E. Long Term Monitoring of High- and Low- Enthalpy Fields Under Exploitation // WGC2000 Short Courses, Japan. 2000. P. 125–152.
  5. Axelsson G., Gunnlaugsson E., Jónasson Th., Ólafsson M. Low temperature geothermal utilization in Iceland – Decades of experience // Geothermics. 2010. № 39. P. 329–338.
  6. Bodvarsson G. Temperature/flow statistics and thermodynamics of low temperature geothermal systems in Iceland // J. Volcanol. Geotherm. Res. 1983. № 19. P. 255–280.
  7. Genter A., Baujard C., Cuenot N. et al. Geology, Geophysics and Geochemistry in the Upper Rhine Graben: the frame for geothermal energy use // European Geothermal Congress 2016, Strasbourg, France, 19–24 Sept. 2016. 5 p.
  8. Johannesson P., Chatenay C., Thorsteinsson H. et al. Technology and innovation can Foster geothermal District Heating Development // An Icelandic Case Study. Strasbourg, EGC-2016, http://www.verkis.com/media/pdf/id-624-Westman-islands-utgefid_mlogo.pdf
  9. Kiryukhin A.V., Asaulova N.P., Vorozheikina L.A. et al. Recharge Conditions of the Low Temperature Paratunsky Geothermal Reservoir, Kamchatka // Russia Procedia Earth and Planetary Science. 2017. № 17. P. 132–135.
  10. Kiryukhin A.V., Vorozheikina L.A., Voronin P.О., Kiryukhin P.A. Thermal-Permeability structure and recharge conditions of the low temperature Paratunsky geothermal reservoirs, Kamchatka, Russia // Geothermics. 2017. 70. P. 47–61.
  11. Kiryukhin A.V., Polyakov A.Y., Usacheva O.O., Kiryukhin P.A. Thermal Hermal-Permeability Structure and Recharge Conditions of the Mutnovsky High Temperature Geothermal Field (Kamchatka, Russia) // J. of Volcanol. and Geotherm. Res. 2018. 356. P. 36–55. doi: 10.1016/j.jvolgeores.2018.02.010
  12. Rybach L. Geothermal Systems, Conductive Heat Flow, Geothermal Anomalies // Geothermal systems. Principles and Case Histories. N.Y.: Pergamon Press, 1981. P. 3–32.
  13. Schill E., Genter A. EGS Geothermal Challenges within the Upper Rhine Valley based on Soultz Experience // Proceedings Third European Geothermal Review, Mainz. 2003. 16 p.

补充文件

附件文件
动作
1. JATS XML
下载

版权所有 © Russian Academy of Sciences, 2019