This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Stemland H, Rodum E, & Johansen H: “ASR – Guidance for structural analysis”. NPRA report No. 601, 2015. Oslo, Norway (In Norwegian).Search in Google Scholar
Johansen H: “Assessment of bridges with alkali-silica-reactions – ASR”. NPRA report No. 855, 2022. Oslo, Norway (In Norwegian).Search in Google Scholar
Stemland K M & Nordhaug K: “Beregning av bru med alkalireaksjoner : Tilstandsvurdering og kapasitetskontroll av Elgeseter bru”. (Master thesis). NTNU, Trondheim, Norway, 2018. (In Norwegian) http://hdl.handle.net/11250/2568090.Search in Google Scholar
Dr.ing Aas-Jakobsen AS: “Beregningsrapport, 11752-35-03 Klassifisering for Bk10/50”. Assessment Report, 2021. Oslo, Norway (In Norwegian).Search in Google Scholar
Stemland K & Stemland H: “Vurdering av ASR-krefter og kapasitet av Elgeseter bru”. Technical Memo, 2022. Trondheim, Norway (In Norwegian).Search in Google Scholar
Sørensen S.I: “Betongkonstruksjoner - Beregning og dimensjonering etter Eurocode 2”. Fagbokforlaget, 2013. Trondheim, Norway (In Norwegian).Search in Google Scholar
Doran D K (Chairman of Task Group): “Structural Effects of Alkali-Silica Reaction: Technical Guidance on the Appraisal of Existing Structures” The Institution of Structural Eningeers, 1992. Great Britain.Search in Google Scholar
Jones, A E K. &. Clark L A: “The effects of ASR on the properties of concrete and the implications for assessment”. Engineering Structures, 1998. 20 (9): p. 785-791.Search in Google Scholar
Barbosa R.A, Hansen S G, Hansen K K, Hoan L C & Grelk B: “Influence of alkali-silica reaction and crack orientation on the uniaxial compressive strength of concrete cores from slab bridges”. Construction and Building Materials, 2018. 176: p. 440-451.Search in Google Scholar
Sørgaard Kongshaug S, Oseland O, Kanstad T, Hendriks M A N, Rodum E & Markeset G: “Experimental investigation of ASR-affected concrete – The influence of uniaxial loading on the evolution of mechanical properties, expansion and damage indices”. Construction and Building Materials, 2018. 245, 118384. https://doi.org/10.1016/j.conbuildmat.2020.118384.Search in Google Scholar
Stemland K M: “Structural strength analysis of concrete structures exposed to Alkali-silica reactions”. (Doctoral thesis), NTNU, Trondheim, Norway, 2023. (In progress).Search in Google Scholar
Stemland K, Rodum E & Kanstad T: “Stiffness damage testing of laboratory-cast alkali-silica reactive concrete and cores drilled from an existing concrete structure”. Proceedings, 16th Internation Conference on Alkali-Aggregate Reaction in Concrete (ICAAR). Lisbon, Portugal. 2022.Search in Google Scholar
Kongshaug SS, Larssen R M, Hendriks M A N, Kanstad T & Markeset G: “Load effects in reinforced concrete beam bridges affected by alkali–silica reaction–Constitutive modelling including expansion, cracking, creep and crushing”. Engineering Structures, 2021. 245: p. 112945.Search in Google Scholar
Sanchez L F M, Fournier B Jolin M & Bastien J: “Evaluation of the stiffness damage test (SDT) as a tool for assessing damage in concrete due to ASR: Test loading and output responses for concretes incorporating fine or coarse reactive aggregates”. Cement and Concrete Research, 2014. 56: p. 213-229. https://doi.org/10.1016/j.cemconres.2013.11.003.Search in Google Scholar
Sanchez L F M, Fournier B, Jolin M & Bastien J: “Practical use of the Stiffness Damage Test (SDT) for assessing damage in concrete infrastructure affected by alkali-silica reaction”. Construction and Building Materials, 2016. 125: p. 1178-1188. https://doi.org/10.1016/j.conbuildmat.2016.08.101.Search in Google Scholar
Sanchez LFM, Fournier B, Jolin M, Mitchell D & Bastien J: “Overall assessment of Alkali-Aggregate Reaction (AAR) in concretes presenting different strengths and incorporating a wide range of reactive aggregate types and natures”. Cement and Concrete Research, 2017. 93: p. 17-31. https://doi.org/10.1016/j.cemconres.2016.12.001.Search in Google Scholar
Villeneuve V, Fournier B & Duchesne J: “Determination of the damage in concrete affected by ASR - The Damage Rating Index (DRI),. Proceedings, 14th International Conference on Alkali-Aggregate Reaction (ICAAR), 2012. Austin, Texas, USA, 2012.Search in Google Scholar
Champagne M, Rodum E, Pedersen BM, Lindgård J, Roy-Tremblay M, Fournier B, Bissonnette B & Duchesne C: “Field and laboratory investigations for the condition assessment of ASR-affected structures”. 2022. (In progress).Search in Google Scholar
Furdal H & Vevang J: “Assessment of Elgeseter Bridge Suffering from Alkali-Silica Reactions: Analysis and capacity verification of the bridge deck with finite element shell models”. Master thesis, NTNU, Trondheim, Norway, 2021.Search in Google Scholar
Trondheim Havn, 2010. https://www.flickr.com/photos/trondheimhavn/4882173842.Search in Google Scholar
Jensen V: “Elgeseter Bridge in Trondheim damaged by alkali silica reaction: microscopy, expansion and relative humidity measurements, treatment with mono silanes and repair” 9th Euroseminar on Microscopy Applied to Building Materials, 2003.Search in Google Scholar
Rodum E, Pedersen B M & Rellin R H: “Field and laboratory examinations of an ASE-affected bridge - Variations in crack extent and water content”. Proceedings, 14th International Conference on Alkali-Aggregate Reaction (ICAAR). Sao Paulo, Brazil, 2016.Search in Google Scholar
Dr.ing Aas-Jakobsen AS: “Elgeseter bridge. Report from special survey”. 2012. Oslo, Norway (In Norwegian)Search in Google Scholar
Standard Norge: “NS 3473 - Prosjektering av betongkonstruksjoner”. 2003. Oslo, Norway (In Norwegian)Search in Google Scholar
Norwegian Public Road Administration (NPRA): “Bruklassifisering, Håndbok R412”. Oslo, Norway, 2014. (In Norwegian).Search in Google Scholar