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Evaluation of geothermal potential of Mataruška Banja Spa (central Serbia) thermal mineral water

Treść / Zawartość
Identyfikatory
Warianty tytułu
Konferencja
XVIIth International Conference of Young Geologists Herl'any 2016
Języki publikacji
EN
Abstrakty
EN
Mataruška Banja Spa is located in central Serbia, around 180 km south of Belgrade on the northern slopes of the mountain massif Stolovi. The spa is characterized by moderate continental climate with an average annual rainfall of 740.3 mm and a mean annual temperature of 11.5°C and the low impact of the wind. Soon after the natural discovery of the existence of hot mineral water in Mataruška Banja Spa, after the floods of the Ibar River in the spring of 1897, the water began to be used for treatment. Although its use as a heat source is also possible, this has not yet been achieved. Yield of over 30 l/s and temperature of 25–52°C from the existing wells are the most important facts when adopting positive assessment of the importance and cost-effectiveness of the application of this completely ecological and renewable resource. In the exploration area, there are 4 exploratory-abstraction wells, 2 dug wells and 3 probes, of which only MB-2/81, is functioning with water temperature of 48°C. Despite the fact that the existence of these hot and healing water has been known for more than 120 years, the utilization for energy purposes has not yet been realized. Thermo mineral water of Mataruška Banja Spa has the highest content of sulphur hydrogen in Serbia – from 21 mg/L to 23 mg/L (Krunic 2012). From the aspect of hydrogeological characteristics, fissure aquifers within serpentinite and hydrothermally altered serpentinite are dominant, where thermo mineral water are accumulated. The circulation of thermo mineral waters is controlled by terrain tectonics, and specifically the existence of faults within the serpentinite and hydrothermally altered serpentinite. For the determination of the temperature in the geothermal reservoir, the calculation according to the formula for chemical geothermometers based on the content of individual components of the chemical composition of hydrogeothermal fluids has been used. Chemical equilibrium between rock minerals and their solution in water is most reliable method of determining the temperature in the reservoir. For temperature determination are attained silica (Fournier 1977) and Na/K ratio (Fournier 1979) geothermometers and analysis of chemical composition of thermo mineral water. According to Cirica (2015) an average temperature value in reservoir is about 150°C. Assumptions and estimates made in earlier studies (Milivojević 1990; Milenić 2008) confirm the results obtained by calculations. Insufficient knowledge of the reservoir is an important reason for interest in research of this reservoir. The assessment of the total geothermal energy has been performed on the basis of the available data on the yield of wells and water temperature from these facilities which is approximately 4283 kW (th). One of the uses of thermo mineral water is for balneological purpose. Therefore, the existing capacity of hydrothermal system will certainly be able to satisfy the upcoming needs of future generations. The aim of the research is to determine feasible options and actual available amount of energy from the existing wells, which is supported by the use of geothermometers regarding content of SiO 2 and Na and K to define the maximum reservoir temperature. Accessibility geothermal energy in this area could bring many benefits, which would reduce the pressure on the use of fossil fuels and reduce greenhouse gas emissions.
Słowa kluczowe
Wydawca
Rocznik
Strony
65--66
Opis fizyczny
Bibliogr. 8 poz.
Twórcy
autor
  • University of Belgrade, Faculty of Mining and Geology, Department of Hydrogeology; Đušina 7, Serbia
autor
  • University of Belgrade, Faculty of Mining and Geology, Department of Hydrogeology; Đušina 7, Serbia
Bibliografia
  • Ćirica N., 2015. Geotermalni potencijal termomineralnih voda Mataruške Banje. Faculty of Mining and Geology, Belgrade [final thesis].
  • Fournier R.O., 1979. A revised equation for the Na/K geothermometer. Transactions – Geothermal Resources Council, 3, 221–224.
  • Fournier R.O. & Potter R.W. II, 1982. A revised and expanded silica (quartz) geothermometer. Geothermal Resources Council Bulletin, 11, 10, 3–12.
  • Karingithi C.W., 2013. Chemical geothermometers for geothermal exploration. [in:] Short Course VII of Exploration for Geothermal Resources, Kenya.
  • Krunić O., 2012. Mineralne vode. Faculty of Mining and Geology, Belgrade.
  • Milivojević M., 2012. Geotermologija i geotermalna energija. Faculty of Mining and Geology, Belgrade.
  • Milenić D., 2008. Prethodna studija o opravdanosti supstucije fosilnog goriva SB Agens u Mataruškoj banji. Faculty of Mining and Geology, Belgrade.
  • Perić J. & Milivojević M., 1990. Studija geotermalne potencijalnosti teritorije SR Srbije van teritorija SAP. Faculty of Mining and Geology, Belgrade.
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b5ac8d3a-51c4-4db9-aae9-2492ceb06aca
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