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Warianty tytułu
Języki publikacji
Abstrakty
The authors present possible applications of thermal data as an additional source of information on an object’s behaviour during the technical assessment of the condition of a concrete surface. For the study one of the most recent propositions introduced by Zoller + Fröhlich company was used, which is an integration of a thermal camera with a terrestrial laser scanner. This solution enables an acquisition of geometric and spectral data on the surveyed object and also provides information on the surface’s temperature in the selected points. A section of the dam’s downstream concrete wall was selected as the subject of the study for which a number of scans were carried out and a number of thermal images were taken at different times of the day. The obtained thermal data was confronted with the acquired spectral information for the specified points. This made it possible to carry out broader analysis of the surface and an inspection of the revealed fissure. The thermal analysis of said fissure indicated that the temperature changes within it are slower, which may affect the way the concrete works and may require further elaboration by the appropriate experts. Through the integration of a thermal camera with a terrestrial laser scanner one can not only analyse changes of temperature in the discretely selected points but on the whole surface as well. Moreover, it is also possible to accurately determine the range and the area of the change affecting the surface. The authors note the limitations of the presented solution like, inter alia, the resolution of the thermal camera.
Słowa kluczowe
Wydawca
Czasopismo
Rocznik
Tom
Strony
35--43
Opis fizyczny
Bibliogr. 17 poz., rys., tab.
Twórcy
autor
- Warsaw University of Technology, Faculty of Geodesy and Cartography, Chair of Surveying Engineering, Measuring and Control Systems, pl. Politechniki 1, room 310, 00-661 Warsaw, Poland
autor
- Warsaw University of Technology, Faculty of Geodesy and Cartography, Chair of Surveying Engineering, Measuring and Control Systems, pl. Politechniki 1, room 310, 00-661 Warsaw, Poland
Bibliografia
- [1] ALBA M.I., BARAZZETTI L., SCAIONI M., ROSINA E., PREVITALI M., Mapping infrared data on terrestrial laser scanning 3D models of buildings, Remote Sensing, 2011, 3(9), 1847-1870.
- [2] COSTANZO A., MINASI M., CASULA G., MUSACCHIO M., BUONGIORNO M.F., Combined use of terrestrial laser scanning and IR thermography applied to a historical building, Sensors, 2015, 15(1), 194-213.
- [3] GONZÁLEZ-AGUILERA D., LAGÜELA S., RODRÍGUEZ-GONZÁLVEZ P., HERNÁNDEZ-LÓPEZ D., Image-based thermographic modeling for assessing energy efficiency of buildings façades, Energy and Buildings, 2013, 65, 29-36.
- [4] HERNÁNDEZ P.A., CALVARI S., RAMOS A., PÉREZ N.M., MÁRQUEZ A., QUEVEDO R., BARRANCOSA J., PADRÓNA E., PADILLAA G.D., LÓPEZB, D., SANTANAB A.R., MELIÁNA G.V., DIONIS S., RODRÍGUEZ F., CALVO D., SANTANA Á.R., Magma emission rates from shallow submarine eruptions using airborne thermal imaging, Remote Sensing of Environment, 2014, 154, 219-225.
- [5] LAGÜELA S., MARTÍNEZ J., ARMESTO J., ARIAS P., Energy efficiency studies through 3D laser scanning and thermographic technologies, Energy and Buildings, 2011, 43(6), 1216-1221.
- [6] LAGÜELA S., DÍAZ-VILARIÑO L., ARMESTO J., ARIAS P., Non-destructive approach for the generation and thermal characterization of an as-built BIM, Construction and Building Materials, 2014, 51, 55-61.
- [7] MALINOWSKI M., SIKORA J., Termograficzna analiza wybranych przegród budowlanych w aspekcie ich termoizolacyjności (Thermographic analysis of selected building partitions in the context of their thermal insulation properties), Infrastruktura i Ekologia Terenów Wiejskich, 2013, 3/IV, (in Polish).
- [8] OSIŃSKA-SKOTAK K., Znaczenie korekcji radiometrycznej w procesie przetwarzania zdjęć satelitarnych (The importance of radiometric correction in satellite images processing, Archiwum Fotogrametrii, Kartografii i Teledetekcji, 2007, 17, (in Polish).
- [9] PASCUCCI S., BASSANI C., PALOMBO A., POSCOLIERI M., CAVALLI R., Road asphalt pavements analyzed by airborne thermal remote sensing: Preliminary results of the venice highway, Sensors, 2008, 8(2), 1278-1296.
- [10] RUTKOWSKA G., KLEPAK O., PODAWCA K., Problemy strat ciepła w istniejących budynkach jednorodzinnych w kontekście błędów wykonawczych (Problems of Heat Loss in Existing Single-family Buildings in the Context of Construc- tion Errors), Annual Set the Environment Protection, 2013, 2625-2639, (in Polish).
- [11] SAARONI H., BEN-DOR E., BITAN A., POTCHTER O., Spatial distribution and microscale characteristics of the urban heat island in Tel-Aviv, Israel, Landscape and Urban Planning, 2000, 48(1), 1-18.
- [12] TITMAN D.J., Applications of thermography in non-destructive testing of structures, NDT & e International, 2001, 34(2), 149-154.
- [13] WANG C., CHO Y.K., GAI M., As-is 3D thermal modeling for existing building envelopes using a hybrid LIDAR system, Journal of Computing in Civil Engineering, 2012, 27(6), 645-656.
- [14] WRÓBEL A., Termografia w pomiarach inwentarskich obiektów budowlanych (Thermography in the measurement of building objects (Postdoctoral Thesis), Monografie 209, AGH, Kraków 2010, (in Polish).
- [15] ZACZEK-PEPLINSKA J., OSIŃSKA-SKOTAK K., WUJANZ D., KOŁAKOWSKA M., Analysis of the possibility for using the results of terrestrial laser scanning (TLS) measurements and classification algorithms of images for the engineering structure surface condition assessment, [in:] F. Humair, B. Matasci, M. Jaboyedoff, A. Abellan, D. Carrea, M.-H. Derron, M. Wyser (Eds.), Vertical geology, from remote sensing to 3D geological modelling, Proceedings of the first Vertical Geology Conference, (pp. 227-232). University of Lausanne, 2014.
- [16] ZACZEK-PEPLINSKA J., KOWALSKA M., NOWAK E., OSIŃSKA-SKOTAK K., Metodyka wykonania oceny stanu powierzchni masywnej konstrukcji betonowej na podstawie klasyfikacji obszarów jednorodnych chmur punktów (TLS) (Methodology of large concrete structure surface condition evaluation based on classification of uniform areas within point clouds (TLS)), [in:] J. Winter, A. Wita (Eds.), Eksploatacja budowli piętrzących – diagnostyka i zapobieganie zagrożeniom, (pp. 373–384), Instytut Meteorologii i Gospodarki Wodnej, Państwowy Instytut Badawczy, 2015, (in Polish).
- [17] Internet sources: http://www.zf-laser.com/fileadmin/editor/Datenblaetter/Datasheet_TCam_e.pdf (online access: 23.11.2016).
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
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