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Abolmaali, A. Mikhaylova, A. Wilson, J. Lundy (2012), Performance of steel fiber-reinforced concrete pipes, Transp Res Rec, 2313(1):168–77.AbolmaaliMikhaylovaA.WilsonA.LundyJ.2012Performance of steel fiber-reinforced concrete pipesTransp Res Rec231311687710.3141/2313-18Search in Google Scholar
Al Rikabi F.T., Sargand S.M., Kurdziel J. (2019), Evaluation of synthetic fiber reinforced concrete pipe performance using three-edge bearing test, J Test Eval., 47(2):942–58.Al RikabiF.T.SargandS.M.KurdzielJ.2019Evaluation of synthetic fiber reinforced concrete pipe performance using three-edge bearing testJ Test Eval.4729425810.1520/JTE20170369Search in Google Scholar
Al Rikabi F.T., Sargand S.M., Kurdziel J., Hussein H.H. (2018), Experimental investigation of thin-wall synthetic fiber-reinforced concrete pipes, ACI Struct J., 115(6):1671–81.Al RikabiF.T.SargandS.M.KurdzielJ.HusseinH.H.2018Experimental investigation of thin-wall synthetic fiber-reinforced concrete pipesACI Struct J.115616718110.14359/51702413Search in Google Scholar
Company information materials, ETUTIT.Company information materials, ETUTITSearch in Google Scholar
Company information materials, PERFECT.Company information materials, PERFECTSearch in Google Scholar
Company information materials, HABA BETON.Company information materials, HABA BETONSearch in Google Scholar
Company information materials, HUMES.Company information materials, HUMESSearch in Google Scholar
De la Fuente A., Escariz R.C., de Figueiredo A.D., Molins C., Aguado A. (2012), A new design method for steel fibre reinforced concrete pipes, Construct Build Mater, 30:547–55.De la FuenteA.EscarizR.C.de FigueiredoA.D.MolinsC.AguadoA.2012A new design method for steel fibre reinforced concrete pipesConstruct Build Mater305475510.1016/j.conbuildmat.2011.12.015Search in Google Scholar
De la Fuente A., Escariz R.C., de Figueiredo A.D., Aguado A. (2013), Design of macro-synthetic fibre reinforced concrete pipes, Construct Build Mater, 43:523–32.De la FuenteA.EscarizR.C.de FigueiredoA.D.AguadoA.2013Design of macro-synthetic fibre reinforced concrete pipesConstruct Build Mater435233210.1016/j.conbuildmat.2013.02.036Search in Google Scholar
Deng Z., Liu X., Chen P. et al. (2021a), Basalt-polypropylene fiber reinforced concrete for durable and sustainable pipe production. Part 1: Experimental Program, Structural Concrete, 1–17.DengZ.LiuX.ChenP.2021aBasalt-polypropylene fiber reinforced concrete for durable and sustainable pipe production. Part 1: Experimental ProgramStructural Concrete11710.1002/suco.202000759Search in Google Scholar
Deng Z., Liu X., Chen P. et al. (2021b), Basalt-polypropylene fiber reinforced concrete for durable and sustainable pipe production. Part 2: Numerical and parametric analysis, Structural Concrete, 1–18.DengZ.LiuX.ChenP.2021bBasalt-polypropylene fiber reinforced concrete for durable and sustainable pipe production. Part 2: Numerical and parametric analysisStructural Concrete11810.1002/suco.202000760Search in Google Scholar
Deng Z., Liu X., Liang N. et al. (2021c), Flexural Performance of a New Hybrid Basalt-Polypropylene Fiber-Reinforced Concrete Oriented to Concrete Pipelines, Fibers, 9(7), 43.DengZ.LiuX.LiangN.2021cFlexural Performance of a New Hybrid Basalt-Polypropylene Fiber-Reinforced Concrete Oriented to Concrete PipelinesFibers974310.3390/fib9070043Search in Google Scholar
Haktanir T., Ari K., Altun F., Karahan O. (2007), A comparative experimental investigation of concrete, reinforced-concrete and steel-fibre concrete pipes under three-edge-bearing test, Construct Build Mater, 21(8):1702–8.HaktanirT.AriK.AltunF.KarahanO.2007A comparative experimental investigation of concrete, reinforced-concrete and steel-fibre concrete pipes under three-edge-bearing testConstruct Build Mater2181702810.1016/j.conbuildmat.2006.05.031Search in Google Scholar
Karwowska J., Łapko A. (2011), Przydatność stosowania nowoczesnych kompozytów fibrobetonowych w konstrukcjach budowlanych, Budownictwo i Inżynieria Środowiska, Vol. 2, No. 1, 41–46.KarwowskaJ.ŁapkoA.2011Przydatność stosowania nowoczesnych kompozytów fibrobetonowych w konstrukcjach budowlanychBudownictwo i Inżynieria Środowiska214146Search in Google Scholar
Kizilkanat A.B., Kabay N., Akyüncü V., Chowdhury S., Akça A.H. (2015), Mechanical properties and fracture behavior of basalt and glass fiber reinforced concrete: an experimental study, Construct Build Mater, 100:218–24.KizilkanatA.B.KabayN.AkyüncüV.ChowdhuryS.AkçaA.H.2015Mechanical properties and fracture behavior of basalt and glass fiber reinforced concrete: an experimental studyConstruct Build Mater1002182410.1016/j.conbuildmat.2015.10.006Search in Google Scholar
Kolonko A., Kolonko A. (2005), Rury i elementy z topionego bazaltu w zastosowaniu do budowy i renowacji przewodów kanalizacyjnych, Gaz, Woda i Technika Sanitarna, Nr 6/2005, 14–19.KolonkoA.KolonkoA.2005Rury i elementy z topionego bazaltu w zastosowaniu do budowy i renowacji przewodów kanalizacyjnychGaz, Woda i Technika SanitarnaNr 6/2005,1419Search in Google Scholar
Lee S., Park Y., Abolmaali A. (2019), Investigation of flexural toughness for steel-and-synthetic-fiber-reinforced concrete pipes, Structure, 19:203–11.LeeS.ParkY.AbolmaaliA.2019Investigation of flexural toughness for steel-and-synthetic-fiber-reinforced concrete pipesStructure192031110.1016/j.istruc.2018.12.010Search in Google Scholar
Madryas C., Wysocki L., Kolonko A. (2002), Konstrukcje przewodów kanalizacyjnych, Oficyna Wydawnicza Politechniki Wrocławskiej.MadryasC.WysockiL.KolonkoA.2002Konstrukcje przewodów kanalizacyjnychOficyna Wydawnicza Politechniki WrocławskiejSearch in Google Scholar
Madryas C. (2007a), Beton w infrastrukturze podziemnej miast przyszłości, Geoinżynieria: drogi, mosty, tunele, Nr 4/2007, 28–35.MadryasC.2007aBeton w infrastrukturze podziemnej miast przyszłościGeoinżynieria: drogi, mosty, tuneleNr 4/2007,2835Search in Google Scholar
Madryas C. (2007b), Współczesne materiały konstrukcyjne w podziemnej infrastrukturze sieciowej miast, Materiały Budowlane, Nr 2/2007, 15–21.MadryasC.2007bWspółczesne materiały konstrukcyjne w podziemnej infrastrukturze sieciowej miastMateriały BudowlaneNr 2/2007,1521Search in Google Scholar
Mohamed N., Soliman A.M., Nehdi M.L. (2014), Full-scale pipes using dry-cast steel fibre-reinforced concrete, Construct Build Mater, 72:411–22.MohamedN.SolimanA.M.NehdiM.L.2014Full-scale pipes using dry-cast steel fibre-reinforced concreteConstruct Build Mater724112210.1016/j.conbuildmat.2014.09.025Search in Google Scholar
Mohamed N., Soliman A.M., Nehdi M.L. (2015), Mechanical performance of full-scale precast steel fibre-reinforced concrete pipes, Eng Struct, 84:287–99.MohamedN.SolimanA.M.NehdiM.L.2015Mechanical performance of full-scale precast steel fibre-reinforced concrete pipesEng Struct842879910.1016/j.engstruct.2014.11.033Search in Google Scholar
Peyvandi A., Soroushian P., Jahangirnejad S. (2013a), Enhancement of the structural efficiency and performance of concrete pipes through fiber reinforcement, Construct Build Mater, 45:36–44.PeyvandiA.SoroushianP.JahangirnejadS.2013aEnhancement of the structural efficiency and performance of concrete pipes through fiber reinforcementConstruct Build Mater45364410.1016/j.conbuildmat.2013.03.084Search in Google Scholar
Peyvandi A., Soroushian P. (2013b), Structural performance of dry-cast concrete nanocomposite pipes, Materials and Structures, 48:461–470.PeyvandiA.SoroushianP.2013bStructural performance of dry-cast concrete nanocomposite pipesMaterials and Structures4846147010.1617/s11527-013-0196-0Search in Google Scholar
Peyvandi A., Ahmed Sbia L., Soroushian P., Sobolev K. (2013), Effect of the cementitious paste density on the performance efficiency of carbon nanofiber in concrete nanocomposite, Constr Build Mater 48:265–269.PeyvandiA.Ahmed SbiaL.SoroushianP.SobolevK.2013Effect of the cementitious paste density on the performance efficiency of carbon nanofiber in concrete nanocompositeConstr Build Mater4826526910.1016/j.conbuildmat.2013.06.094Search in Google Scholar
Sim J., Park C., Moon D.Y (2005), Characteristics of basalt fiber as a strengthening material for concrete structures, Compos Part B Eng., 36(6):504–12.SimJ.ParkC.MoonD.Y2005Characteristics of basalt fiber as a strengthening material for concrete structuresCompos Part B Eng.3665041210.1016/j.compositesb.2005.02.002Search in Google Scholar
Szruba M. (2017), Rury w infrastrukturze, Nowoczesne Budownictwo Inżynieryjne, nr 1, s. 42–47.SzrubaM.2017Rury w infrastrukturzeNowoczesne Budownictwo Inżynieryjne14247Search in Google Scholar