Identyfikatory
Warianty tytułu
Evaluation of structural materials corrosion rate on the base of emission of pollutants
Języki publikacji
Abstrakty
Przedstawiono metody przetwarzania danych doświadczalnych uzyskiwanych podczas monitorowania korozji oraz modelowania rozprzestrzeniania się zanieczyszczeń w atmosferze i szybkości korozji do przewidywania trwałości materiałów konstrukcyjnych i zabezpieczeń antykorozyjnych w infrastrukturze przemysłowej i drogowej.
The methods of processing of experimental data obtained during the corrosion monitoring as well as modeling the propagation of pollutants in the atmosphere and corrosion rates to predict the durability of structural materials and corrosion protection in industrial and road infrastructure were presented.
Czasopismo
Rocznik
Tom
Strony
4099--4104, CD2
Opis fizyczny
Bibliogr. 11 poz., rys., tab.
Bibliografia
- 1. Vernon W. H. J.; A laboratory study of the atmospheric corrosion of metals. Trans. Faraday Soc., 31, 1668-1700, 1936
- 2. J. Tidblad, A. A. Michailov, V. Kucera, Development of dose-response functions for the revision of ISO 9223 and comparison of calculated and experimental data, documents of ISO/TC 156-N384,2001
- 3. V. Kucera, J. Tidblad, K. Kreislova, D.Knotkova, M. Faller, D. Reiss, R. Snethlage, T. Yates, J. Henriksen, M. Schreiner, UN/ECE ICP Materials Dose-response Functions for the Multi-pollutant Situation , Water, Air, & Soil Pollution: Focus,7, 1-3, (2007), 249-2582.
- 4. CYTED Program, Subprogram XV.I, Project XV.I, Morcillo M. “Atmospheric Corrosion in Iberoamerica-MICAT Project”, ASTM STP 1239, Kirk W.W., Lawson H.H., eds. American Society for Testing and Materials, Philadelphia, (1995), 257-275
- 5. Kobus J., Kwiatkowski L., Monitorowanie zagrożeń korozyjnych i ich skutków w warunkach korozji atmosferycznej, Inżynieria Powierzchni 1, (2009), 3-15
- 6. Reiss D., Rihm B., Thöni C., Faller M.; Mapping Stock at Risk and Release of Zinc and Copper in Switzerland—Dose Response Functions for Runoff Rates derived from Corrosion Rate Data, Water, Air, and Soil Pollution, 159, 1, 2004, 101-113
- 7. S. Feliu, M. Morcillo, S. Feliu, Jr, The Prediction of Atmospheric Corrosion from Meteorological and Pollution Parameters. Annual Corrosion, Corrosion Science, 3, 34, 403-414, 1993
- 8. L. Ośródka, E. Krajny, M. Wojtylak, The use of numerical weather forecast for air pollution forecasting in an urban industrial agglomeration, 4th Annual Meeting EMS and 5th EC on Applied Climatology (ECAC), Nice, France, 2004
- 9. Oettl D., Kukkonen J., Almbauer R. A., Sturm P. J., Pohjola M., Härkönen J.: Evaluation of a Gaussian and a Lagrangian model against a roadside data set, with emphasis on low wind speed conditions, Atmospheric Environment, 35, 12, 2001, 2123-2132
- 10. H. D., Kalliampakos G., Mapping Atmospheric Corrosion on Materials of Archaeological Importance in Athens, Water, Air, & Soil Pollution, 223, 5, 2012, 2169-2180
- 11. Haagenrud S. E., Henriksen J. F., Skancke T.; Mapping of urban material degradation from available data, Water, Air, and Soil Pollution, 85, 8, 1995, 2667-2672
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-6e168a38-d10f-47f5-ba21-3de8192934eb