Alexander, M. & Beushausen, H. durability, prediction of lifespan and modeling for reinforced concrete structures – review and criticism. Cem. Concr res. 12217–29 (2019).
Google Scholar
Kandasamy, S. & Kothandaraman, S. Influence of the controlled permeable formwork letters on the surface quality of self -binding concrete. Build restriction. Mater. 2601–7 (2020).
Google Scholar
Kandasamy, S., Gowthaman, M., Gowdhamramkarthik, P., Venkatesh Marshall Raman, J. & Magenthiran, B. strength and durability performance of Betonguss using a permeable Forwork Liner. J Buil Patho & Rehabili 9(86). (2022).
Kandasamy, S., Gowdhamramkarthik, P., Syed Ibrahim, S., Chandra Bose, S., Thulasirajan, K. & R. & The effect of permeable formwork on the durability and corrosion performance of concrete. Fall Stud. Mater Build. 16E00838 (2022).
Google Scholar
Shyha, I., Richardson, A., Coventry, K. & Ponton, H. Mold Release technologies with regard to surface procurement. Magazine CONCR res. 68 (2), 87–98 (2016).
Google Scholar
Krishhnan, T. & Telkar, SK influence of non -violent material as a controlled Permable Forwork Liner in concrete. Mater. Today: drive away. 64 (2), 1048-1053 (2022).
Google Scholar
Price, WF controlled permeability character, Ciria reportC 511 (2000).
Ambad, V., Narwadeb, R. & Nagarajanc, K. Influence of controlled permeable formwork against chloride penetration on the concrete structures. J. Res. Closely. Structure. Mater. 8 (1), 117–126 (2021).
Google Scholar
Law, DW, Molyneaux, T. & Aly, T. Long -term performance of controlled permeability formwork. Aust J. Civ. Bogus. 15117–125 (2017).
Google Scholar
Herrmann, M. et al. Flexible formwork technologies – a state of the art. Structure. Concr. 17 (6), 1–48 (2016).
Google Scholar
Kandasamy, S. & Kothandaraman, S. The impact of the formwork committee on the lifespan of self -made concrete. Asia J. Civ. Closely. 21 (7), 1239–1247 (2020).
Google Scholar
Adam, AA, Molyneaux, TC, Patnaikuni, I. & Law, D. The effect of controlled permeability formwork on the healing of concrete. Prog Mecha Struct. & Mater. CRC Press 611–615 (2020).
Kandasamy, S. & Kothandaraman, S. Effect of the formwork committee on durability and corrosion properties of self -made concrete. KSce J. Civ. Closely. 25 (6), 2046–2052 (2021).
Google Scholar
Li, W., Lin, X., Bao, DW & XIE, YM A review of formwork systems for modern concrete construction. Structures 3852–63 (2022).
Google Scholar
Schulte Holacht, R., Merkel, M., Breit, W. & Raupach, M. Monitoring of the microstructural deterioration of concrete, which are exposed to leaching in cleaned water. Civil. Engg des. 4 (4), 99-109 (2022).
Google Scholar
Ye, J., Yu, L. & Chen, Y. Study on the spleens' effect of the controlled permeability sharp liners on the early shrinkage of box girders concrete. J. Adv. Mater. Sci. Bogus. 41502791–8 (2019).
Google Scholar
Aissoun, BM, Gallias, JL & Khayat, KH Influence of formwork material on the transport properties of self -consolidating concrete near educated surfaces. Build restriction. Mater. 146329–337 (2017).
Google Scholar
Garg, S., NIM, KS, Bajpai, KK & Misra, S. Improvement of the quality of near -near space concrete using some formwork leaves. Build restriction. Mater. 207722–733 (2019).
Google Scholar
Guo, BL, Wang, BM, Han, Y. & Jiang, R. Improvement of the specific property with controlled permeability history. Roman Magazin Mater. 50379–386 (2020).
Google Scholar
Megid, Wa & Khayat, KH variations of the surface quality of the self-consolidation and high-tableable concrete with formwork material. Build restriction. Mater. 238117638 (2020).
Google Scholar
Sørensen, He & Poulsen, SL effect of the healing regime and controlled permeability formwork in the early chloride penetration in flight ash concrete, in book: High -Tech -Bed: where technology and engineering meet, jumpers, cham, January. (2018).
Google Scholar
Menaka, B., Sundari, S. & Kumar, GA An overview of the effect of the controlled Permable Forwork (CPF) interior system on concrete. Inter J. Adv. Ang Managing. 4 (1), 527–532 (2022).
Google Scholar
Tahmoorian, F., Nemati, S. & Soleimani, A. A state of the art on the structural performance of fabric shell systems. One. Sol. 849–62 (2020).
Google Scholar
Kandasamy, S. & Kotandaraman, S. Influence of the controlled permeable formwork lines on the lifespan of reinforced concrete. J. Mater. Civil. Meadow. 33 (6), 04021103 (2021).
Google Scholar
Kothandaraman, S. & Kandasamy, S. The impact of the controlled Permable Forwork (CPF) on the surface quality of concrete. Cem. Conc comp. 7648–56 (2017).
Google Scholar
Kothandaraman, S. & Kandasamy, S. The impact of controlled permeable formwork linings on the mechanical properties of concrete. Mother. structure. 494737–4747 (2016).
Google Scholar
Kothandaraman, S., Kandasamy, S. & Sivaraman, K. Studies on the effects of controlled permeable formwork letters on the properties of self -made concrete. Build build. Mater. 118319–326 (2016).
Google Scholar
QURESHI, A. & Ahmed, A. An investigation into strength properties of glass fibers reinforced concrete. Inter J. Eng. Res. Technology. 2 (4), 2567–2572 (2013).
Google Scholar
Chandramouli, K., Srinivasa Rao, P., Pannirsselvam, N., Sekhar, S., Sravana, P. & T. & Starch Properties of fiber fiber concrete. Arpn J. Eng. Appl. Sci. 5 (4), 1–6 (2010).
Google Scholar
Afrooughhsabet, V., Biolzi, L. & Özbakkaloğlu, T. High -Performance -Fiber -reinforced concrete: A review. J. Mater. Sci. 516517–6551 (2016).
Asokan, P., Osmani, M. & Price, ADF improvement of the mechanical properties of fiber -fiber reinforced plastic waste powdered concrete. Build restriction. Mater. 24448–460 (2010).
Google Scholar
Alam, Md, Ahmad, I. & Rahman, F. Experimental investigation of the properties of fiber optic reinforced concrete. Interns J. Eins. Trens tech. 24 (6), 297-301 (2015).
Google Scholar
Soong, Wh, Raghavan, J. & Rizkalla, SH Basic mechanisms of binding fiber enhanced polymer reinforcement on concrete. Build restriction. Mater. 252813–2821 (2011).
Google Scholar
Taskenw, St & Lubell, as mechanical properties of glass fibers reinforced ceramic concrete. Build restriction. Mater. 51215–224 (2014).
Google Scholar
Tian, D. et al. Waste glazing powder as a high temperature stabilizer in mixed oil borehole paste: hydration, microstructure and mechanical properties. Build restriction. Mater. 439137359 (2024).
Google Scholar
XU, L., Hongwei, L., Percy, Mi & Shao-Bo, K. Prediction of the behavior of steel reinforcement in concrete under static and dynamic stress due to finite element, deep learning and analytical methods. Engg fail. Analyze. 161108312 (2024).
Google Scholar
Wei, Z., Xinze, Y., Jinwei, L., Benqing, L. & Yiqun, H. Experimental and numerical examination for torsion behavior of rectangular hollows, reinforced concrete columns that have been strengthened by CFRP. Structures 70107690 (2024).
Google Scholar
Zhangong, J. et al. Synergist preparation and properties of ceramic foams from tungsten-tailings and with a high borosilic waste glass. Build restriction. Mater. 457139367 (2024).
Google Scholar
Zhangong, J. et al. Contrasting effects of waste glass and Scheelite-Sailings Addits on the properties of foam ceramics based on tails and its mechanisms. J. Clean. Produce. 450142025 (2024).
Google Scholar
IS: 8112: 2013, specification for ordinary Portland cement – 43 class, Bureau of Indian standards, Neu -Delhi. (2013).
IS: 383:. Specification for coarse and fine aggregate from natural sources for concrete, Bureau of Indian standards, Neu -Delhi. (2016). (2016).
Is: 456.:2021, simple and reinforced concrete, practice code (Bureau of Indian Standards, 2021).
IS: 9103: 2018, specification for concrete additions, Bureau of Indian Standards, Neu -Delhi. (2018).
IS: 10262. Guidelines of concrete mixture, proportionation, Bureau of Indian standards, Neu -Delhi. (2019). (2019).
AStM B 276.:2015, standard test method for the apparent porosity in cemented carbids (American Society for Testing Materials, 2015).
IS: 516: 2018. Test methods for the strength of concrete (Bureau of Indian Standards, 2018).
IS: 5816: 2018. Test method for the distribution of the tensile strength of concrete (Bureau of Indian Standards, 2018).
AStM A 956.:2022, standard test method for LEEB Hardening testing of steel products (American Society for Test Materials, 2022).
Astm E 18.:2022, standard test method for the Rockwell hardness of metallic materials (American Society for Test Materials, 2022).
Is: 13311. Part 2: 2018, test methods for non-destructive tests from concrete (Bureau of Indian Standards, 2018).
Neville, at Properties of Concrete, Pearson Education, India, 4. Ed. (1995).