Research of the environmental temperature influence on the horizontal displacements of the Dnieper hydroelectric station dam (according to GNSS measurements)

(2020). Action plan for adaptation to the effects of climate change in the city of Zaporizhia. The project was approved by the decision of the 50th session of the City Council No. 38 from 3.06.2020. Last accessed January 2022. Search in Google Scholar

Chrzanowski, A., Szostak, A., and Steeves, R. (2011). Reliability and efficiency of dam deformation monitoring schemes. In Proceedings of the 2011 Annual Conference of Canadian Dam Association (CDA/ACB), Fredericton, NB, Canada, 15 October 2011, volume 15. Search in Google Scholar

Corsetti, M., Fossati, F., Manunta, M., and Marsella, M. (2018). Advanced SBAS-DInSAR technique for controlling large civil infrastructures: An application to the Genzano di Lucania dam. Sensors, 18(7):2371, doi:10.3390/s18072371.10.3390/s18072371 Search in Google Scholar

Drummond, P. (2010). Combining CORS Networks, Automated Observations and Processing, for Network RTK Integrity Analysis and Deformation Monitoring. In Proceedings of the 15th FIG Congress Facing the Challenges, Sydney, Australia, 11–16 April 2010, pages 11–16. Search in Google Scholar

Kang, F. and Li, J. (2020). Displacement model for concrete dam safety monitoring via gaussian process regression considering extreme air temperature. Journal of Structural Engineering, 146(1):05019001, doi:10.1061/(ASCE)ST.1943-541X.0002467.10.1061/(ASCE)ST.1943-541X.0002467 Search in Google Scholar

Kuzmanovic, V., Savic, L., and Mladenovic, N. (2013). Computation of thermal-stresses and contraction joint distance of rcc dams. Journal of Thermal Stresses, 36(2):112–134, doi:10.1080/01495739.2013.764795.10.1080/01495739.2013.764795 Search in Google Scholar

Léger, P. and Leclerc, M. (2007). Hydrostatic, temperature, time-displacement model for concrete dams. Journal of engineering mechanics, 133(3):267–277, doi:10.1061/(ASCE)0733-9399(2007)133:3(267).10.1061/(ASCE)0733-9399(2007)133:3(267) Search in Google Scholar

Mata, J., Tavares de Castro, A., and Sá da Costa, J. (2013). Time-frequency analysis for concrete dam safety control: Correlation between the daily variation of structural response and air temperature. Engineering Structures, 48:658–665, doi:10.1016/j.engstruct.2012.12.013.10.1016/j.engstruct.2012.12.013 Search in Google Scholar

Milillo, P., Bürgmann, R., Lundgren, P., Salzer, J., Perissin, D., Fielding, E., Biondi, F., and Milillo, G. (2016). Space geodetic monitoring of engineered structures: The ongoing destabilization of the mosul dam, iraq. Scientific reports, 6(1):37408, doi:10.1038/srep37408.10.1038/srep37408513863727922128 Search in Google Scholar

Moroko, V. (2010). Dniproges: Black August 1941. Scientific works of the historical faculty of Zaporizhia National University. Search in Google Scholar

Oro, S., Mafioleti, T., Chaves Neto, A., Garcia, S., and Neumann, C. (2016). Study of the influence of temperature and water level of the reservoir about the displacement of a concrete dam. International Journal of Applied Mechanics and Engineering, 21(1):107– 120, doi:10.1515/ijame-2016-0007.10.1515/ijame-2016-0007 Search in Google Scholar

Santillán, D., Salete, E., and Toledo, M. (2015). A methodology for the assessment of the effect of climate change on the thermal-strain-stress behaviour of structures. Engineering Structures, 92:123–141, doi:doi.org/10.1016/j.engstruct.2015.03.001. Search in Google Scholar

Scaioni, M., Marsella, M., Crosetto, M., Tornatore, V., and Wang, J. (2018). Geodetic and remote-sensing sensors for dam deformation monitoring. Sensors, 18(11):3682, doi:10.3390/s18113682.10.3390/s18113682626387830380693 Search in Google Scholar

Tretyak, K. and Palianytsia, B. (2021). Research of seasonal deformations of the dnipo hpp dam according to gnss measurements. Geodynamics, 30(1):5–16, doi:10.23939/jgd2021.01.005.10.23939/jgd2021.01.005 Search in Google Scholar

Tretyak, K., Periy, S., Sidorov, I., and Babiy, L. (2015). Complex high accuracy satellite and field measurements of horizontal and vertical displacements of control geodetic network on dniester hydroelectric pumped power station (hpps). Geomatics and environmental engineering, 9(1):83–96, doi:10.7494/geom.2015.9.1.83.10.7494/geom.2015.9.1.83 Search in Google Scholar

Yigit, C. O., Alcay, S., and Ceylan, A. (2016). Displacement response of a concrete arch dam to seasonal temperature fluctuations and reservoir level rise during the first filling period: evidence from geodetic data. Geomatics, Natural Hazards and Risk, 7(4):1489–1505, doi:10.1080/19475705.2015.1047902.10.1080/19475705.2015.1047902 Search in Google Scholar

Zhang, Y., Yang, S., Liu, J., Qiu, D., Luo, X., and Fang, J. (2018). Evaluation and analysis of dam operating status using one clock-synchronized dual-antenna receiver. Journal of Sensors, 2018:9135630, doi:10.1155/2018/9135630.10.1155/2018/9135630 Search in Google Scholar