Compulsory and forbidden actions in galvanized and Duplex coatings application

Królikowska, Agnieszka; Bonora, Pier Luigi; Paszek, Urszula

doi:10.15199/33.2025.10.05

Artykuł - szczegóły

Tytuł artykułu

Compulsory and forbidden actions in galvanized and Duplex coatings application

Autorzy

Królikowska Agnieszka , Bonora Pier Luigi , Paszek Urszula

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.15199/33.2025.10.05

Warianty tytułu

Konieczne i zabronione postępowanie przy aplikacji powłok cynkowych zanurzeniowych i systemów Duplex

Języki publikacji

EN PL

Abstrakty

HDG (Hot Dip Galvanized Coatings) and Duplex System are the protection methods widely used in various areas of the economy, including construction and infrastructure. This article aims to highlight the possible preventive interventions inherent to these mentiored protection technologies, dealing with the effects of steel composition, shape, dimensions and detailed structure of the parts to be hot dip galvanized as well as composition and other features of the molten Zinc bath. The dependency of the service life of the treated objects as a function of both environment and other metals connections are analyzed with life examples. The complex procedures suitable to provide a safe extension of both the inner zinc coating and the metal structure itself under the organic coating are examined together with possible mistakes and carelessness which might heavily affect the efficiency of the system.

Cynkowe powłoki ogniowe i system Duplex są metodami ochrony powszechnie stosowanymi w różnych dziedzinach gospodarki, w tym w budownictwie i infrastrukturze. W artykule wskazano możliwe interwencje zapobiegawcze związane z wymienionymi technologiami ochrony, zajmując się wpływem składu stali, kształtu, wymiarów i szczegółowej struktury części, które mają być cynkowane ogniowo, a także składu i innych cech kąpieli stopionego cynku. Przeanalizowano zależność żywotności obiektów poddanych obróbce w funkcji zarówno środowiska, jak i połączeń z innymi metalami na przykładach. Zbadano złożone procedury odpowiednie do zapewnienia bezpiecznego przedłużenia zarówno wewnętrznej powłoki cynkowej, jak i struktury metalowej pod powłoką organiczną wraz z możliwymi błędami i nieostrożnością, które mogą poważnie wpłynąć na efektywność systemu.

Słowa kluczowe

Wydawca

Wydawnictwo SIGMA-NOT

Czasopismo

Materiały Budowlane

Rocznik

2025

Tom

nr 10

Strony

37--47

Opis fizyczny

Bibliogr. 37 poz., il.

Twórcy

autor

Królikowska Agnieszka

Instytut Badawczy Dróg i Mostów

https://orcid.org/0000-0002-0378-0386

autor

Bonora Pier Luigi

autor

Paszek Urszula

urszula.paszek@ibdim.edu.pl

Instytut Badawczy Dróg i Mostów

https://orcid.org/0000-0002-6137-9099

Bibliografia

[1] Saeedikhani M., Wijesinghe S.L., Blackwood D.J. Barrier and Sacrificial Protection Mechanisms of Zinc Rich Primers. Engineering Journal. 2019, 23, 224-233.
[2] Hussain A.K., Seetharamaiah N., Pichumani M., Shilpa Chakra Ch. Research Progress in Organic Zinc Rich Primer Coatings for Cathodic Protection of Metals – A Comprehensive Review. Progress in Organic Coatings. 2021, 153, 106040.
[3] Kalendová A., Kalenda P., Veselý D. Comparison of the efficiency of inorganic nonmetal pigments with zinc powder in anticorrosion paints. Progress in Organic Coatings. 2006, 57, 1-10.
[4] Park J.H., Yun T.H., Kim K.Y., Song Y.K., Park J.M. The improvement of anticorrosion properties of zinc-rich organic coating by incorporating surface-modified zinc particle. Progress in Organic Coatings. 2012, 74 (1), 25-35.
[5] Meroufel A., Touzain S. EIS characterisation of new zinc-rich powder coatings. Progress in Organic Coatings. 2007, 59 (3), 197-205.
[6] Ma Q., Wang L., Sun W., Yang Z., Wang S., Liu G. Effect of chemical conversion induced by self-corrosion of zinc powders on enhancing corrosion protection performance of zinc-rich coatings. Corrosion Science. 2022, 194, 109942.
[7] Saeedikhani M., Wijesinghe S., Blackwood D.J. Revisiting Corrosion Protection Mechanisms of a Steel Surface by Damaged Zinc-Rich Paints. Corrosion. 2019, 75 (7), 756-770.
[8] Knudsen O.Ø., Skilbred A.W.B., Løken A., Daneshian B., Hoche D. Correlations between standard accelerated tests for protective organic coatings and field performance. Materials Today Communication. 2022, 31, 103729.
[9] Ogle K., Morel S., Jacquet D. Observation of self-healing functions on the cut edge of galvanized steel using SVET and pH microscopy. Journal of the Electrochemical Society. 2006, 153 (1), B1-B5.
[10] Dolgikh O., Simillion H., Lamaka S.V., Bastos A.C., Xue H.B., Taryba M.G., Oliveira A.R., Allély C., Van Den Bossche B., Van Den Bergh K., De Strycker J. Corrosion protection of steel cut-edges by hot-dip galvanized Al (Zn, Mg) coatings in 1 wt% NaCl: Part I. Experimental study. Materials and Corrosion, 2019, 70 (5), 768-779.
[11] Dolgikh O., Simillion H., Lamaka S.V., Bastos A.C., Xue H.B., Taryba M.G., Oliveira A.R., Allély C., Van Den Bossche B., Van Den Bergh K., De Strycker J. Corrosion protection of steel cut-edges by hot-dip galvanized Al (Zn, Mg) coatings in 1 wt% NaCl: Part II. Numerical simulations.Materials and Corrosion. 2019, 70 (5), 780-792.
[12] Boshkov N., Petrov K., Kovacheva D., Vitkova S., Nemska S. Influence of the alloying component on the protective ability of some zinc galvanic coatings. Electrochimica Acta. 2005, 51 (1), 77-84.
[13] Kania H., Mendala J., Kozuba J., Sternus M. Development of Bath Chemical Composition for BatchHot-Dip Galvanizing – A Review. Materials. 2020, 13 (18), 4168.
[14] Arguillarena A., Margallo M., Urtiaga A. Carbon footprint of the hot-dip galvanisation process using a 5 life cycle assessment approach. Cleaner Engineering and Technology. 2021, 2,100041.
[15] Charters F.J., O’Sullivan A.D., Cochrane T.A. Influences of zinc loads in urban catchment runoff: Roof type, land use type, climate and management strategies. Journal of Environmental Management. 2022, 322, 116076.
[16] Baran J. Ślad węglowy organizacji i produktu w branży galwanotechnicznej. Biuletyn Galwanotechnika. 2023, 42 (57), 5-10.
[17] Highway Design Manual CALTRANS 2019 California Department of Transportation.
[18] Pingera T., Brandta M., Grothe S., Marginean G. Abrasive Wear Behavior of Batch Hot-Dip Galvanized Coatings. Materials. 2024, 17, 1547.
[19] Sepper S., Peetsalu P., Kulu P., Saarna M. The role of silicon in the hot dip galvanizing process. Proceedings of the Estonian Academy of Sciences. 2016, 65, 2, 159-165.
[20] Pokorny P., Kolisko J., Balik L., Novak P. Effect of chemical composition of steel on the structure of hot–Dip galvanized coating. Metalurgija. 2016, 55 (1), 115-118.
[21] http://www.gavanizeit.org/
[22] Yu Z., Hu J., Mengh H. A Review of Recent Developments in Coating Systems for Hot-Dip Galvanized Steel. Frontiers in Materials. 2020, 7: 74.
[23] Królikowska A., Komorowski L., Bonora P.L. Pitting Corrosion of Hot-Dip Galvanized Coatings. Materials. 2020, 13 (9), 2031.
[24] Królikowska A., Komorowski L. Wpływ dodatków stopowych bizmutu i ołowiu na odporność korozyjną powłok cynkowych zanurzeniowych – Morfologia powłok. Ochrona przed Korozją. 2015, 10, 350-357.
[25] ISO 12944-2:2017 Paints and varnishes – Corrosion protection of steel structures by protective paint systems Part 2: Classification of environments
[26] Królikowska A., Komorowski L. Ocena przyczyn uszkodzeń powłok antykorozyjnych na słupach odgromowych stacji 400 kV, Ochrona przed Korozją. 2023, 66, 237-242.
[27] Maass P., Peissker P. Handbook of Hot-dip Galvanization, Wiley-VCH:Veinheim, Germany. 2011.
[28] Schulz W.D., Thiele M. General hot-dip galvanizing, Eugen G. Leuze Verlag KG, Bad Saulgau. Germany, 2012.
[29] Bonora P.L., Królikowska A. Lack of Basic Corrosion Control Results in Catastrophes. Materials Performance. 2015, 54 (11), 52-54.
[30] Gagné M., Øystein Knudsen O. Duplex Zinc Coatings for Steel Bridges. Materials Performance 2021, https://www.materialsperformance.com/articles/coating-linings/2021/11/duplex-zinc-coatings-for-steel-bridges.
[31] Lozrt J., Votava J., Šmak R. Duplex anti-corrosion protection of steel using a combination of hot-dip galvanising and water-soluble paints. Acta Technologica Agriculturae. 2021, 24, 129-135.
[32] Mills D.J., Jamali S. Effect of different surface preparations prior to painting on the corrosion behavior and surface activity of mild steel. Proceedings of EUROCORR 2010, Moscow.
[33] Bastos A.C., Quevedo M.C., Karavai O.V., Ferreira M.G.S. Review – On the Application of the Scanning Vibrating Electrode Technique (SVET) to Corrosion Research. Journal of The Electrochemical Society. 2017, 164 (14), C973-C990.
[34] ASTM D6386-22 Standard Practice for Preparation of Zinc (Hot-Dip Galvanized) Coated Iron and Steel Product and Hardware Surfaces for Painting.
[35] ASTM D7803-19 Standard Practice for Preparation of Zinc (Hot-Dip Galvanized) Coated Iron and Steel Product and Hardware Surfaces for Powder Coating.
[36] Lovchinov K., Gergova R., Alexieva G. Structural, Morphological and Optical Properties of Nanostructured ZrO2 Films Obtained by an Electrochemical Process at Different Deposition Temperature. Coatings. 2022, 12 (7), 972.
[37] Stambolova I., Dimitrov O., Vassilev S., Yordanov S., Blaskov V., Boshkov N., Shipochka M. Preparation of newly developed 578 CeO2/ZrO2 multilayers: effect of the treatment temperature on the structure and corrosion performance of stainless steel. Journal of Alloys and Compounds. 2019. 806, 1357-136.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-1885af1f-3af4-4e7b-aee1-aeb351ffdb7e